Quantum Broadband Antenna (Part 4 of ...)

This connection of the metal box springs wire design moves light to the right to left-handed of the crystal surface to the edge of this rectangle, as shown in FIG. 1, #3, #5 and the left-to-right is the substrate composite antenna directivity diagram grid that encompasses the entire rectangle square base shown in FIG. 1, #11 through #33. The wave which hits the metal box springs which is reflected first and must come back because of the size of the electromagnetic field and redirected to the middle incoming incident wave. Physical Review Letters, Vol. 90, #5, Feb. 7, 2003, by Yong-Yuan-Zhu states that a new type of polariton in a piezoelectric super lattice produces transverse polarization which can be induced by a longitudinal direction which couples strongly to the electromagnetic wave in the frequency region, shown in FIG. 10, between #121 and #124 which is #122. These polarizations shown in FIG. 10 have four movements that contradict one another but are separated by sectorial zoning metamaterials while the oval wire is electrically compressed at the center of gravity at FIG. 1, #29 is a zero order rediffracted beam which is related to dark matter particles at 10 12 that conducts a radio wave at 103 resulting in a totally new type of polariton based upon this new metal box springs design grid. This electrically induced contraction expansion of light gravity process connects onto the complex oxide metal box springs design. This concept is explained in Physical Review Letters, Vol. 102, 30 Jan. 2009, Deep Sub-wavelength Terahertz Waveguides Using Gap Magnetic Plasmon by Shuang Zhang: this subwavelength terahertz waveguide based on magnetic plasmon polariton mode guided by narrow gap in negative permeability metamaterials in this sectorial zoning redirecting the continuous constance coupling on to the metal box springs design. As in this article it is also in this invention that the metal box springs confining and steering electromagnetic waves at dimensions much smaller than the wavelength compacted in a miniaturization of Einstein's universe of space and time integrating new optical metamaterials on a nanoscale to produce a new antenna device which improves the spatial resolution in optical imaging, holding the incoming light wave and separating the incoming white light signal at the same time. The size of this metal box springs wire optical waveguide is smaller than half of the wavelength in this sectorial zoning imbedded in the new metamaterial medium. These unnatural magnetic metamaterials can extend the magnetic responses to the terahertz and optical frequencies well beyond the limit of what natural materials offer. The reconnective process stated in the claims and the embodiment conclusively proves that these magnetic activities are enhanced by sectorial zoning that provides unique electromagnetic guiding configurations to manipulate the refluxtivity of light wave more efficiently through these magnetic metamaterials in conjunction with the multi-parallel transparent metal-plate waveguides that realize the two-dimensional confinement and guiding of these terahertz waves in deep subwavelength scale. The unique design, as can be seen in FIG. 1, #1, is flat and horizontal but the incoming wave is vertical and then is guided down to the flat metal box springs configuration. In conjunction with the metal box springs design is a multi-dual flat-sided metamaterials made of silver wire core which is the chosen metal and a coating of Ba2Nd5Ti9O27 and benzocyclobutene, which are high- and low-permittivity dielectrics corresponding transmission spectrum of the electric field in this lamination along the arrayed right angles to the metal box springs plane, as shown in FIG. 1, #5 and #6, repetitively, FIG. 3, #56, FIG. 4, #80, # 84, #85, FIG. 10, #119, 125. This process is a transformation optics idea of controlling the fabric of sectorial zoning as a substrate of electromagnetic space and therefore light propagation by filling it with substrate metamaterial, as mentioned above, requiring media metal box spring with coordinate-dependant parameters such as quantum oval loops to complete the coupling constance which is the most important connection to the electron. These coupled oscillations of electrons and light are known as plasmons in the metal box springs design of complex oxide nanostructures which produce the broadband frequencies on a terahertz spectral range. These metamaterials can slow light, thereby increasing the interaction time with nonlinear medium imbedded in it, such as quantum oval loop design which helps concentrating the local field and thus enhancing a nonlinear response. These metamaterial substrates in a sectorial zoning arrangement create the folding phase change on each west-to-east edge and north-to-south edge which causes the folding under and switching for the process that will not cause the breaking and disconnecting the incoming signal connection of the incoming signal. As stated in the specifications, embodiment and claims of this invention, this switchable and holding are controlled by the sectorial zoning metamaterials. This is conclusively based on the metal box springs arrays of micro-macro-nano electrochemical/mechanical design. The above statements are related to the Science article, 30 Apr. 2010, Vol. 328, pages 582-583, Applied Physics, The Road Ahead for Metamaterials by Nikolay I. Zheludev. This is due to the manmade unnatural metamaterial sectorial zoning trapping and coupling effect between the layered box spring design that produces the distinct feature of the 2-subband dual-deck system of this metal box springs as depicted in FIG. 1, FIG. 2, and FIG. 3. This process involves the new metamaterial sectorial zoning boundary separators between each electromagnetic field of layering crystals that are stacked in a substrate plate design that creates the transport of more than one frequency for the nonentanglement gathering component in the incoming oscillation signal. This will produce a special broadband wire cavity performance movement mode that utilizes broadband, wideband, and passband onto the metal box springs that is imbedded in the substrate coupling movement from left to right, right to left, and east to west and north to south, according to Physical Review Letters, Vol. 102, 27 Mar. 2009, article Selection Rules for the Nonlinear Interaction of Gravity Waves by Chung-Hsiang concerning two intersecting beams of internal gravity waves which will generically create two wave-packets by nonlinear interaction. And as stated in Physical Review Letters, Vol. 99, 6 Jul. 2007, Terahertz Frequency Standard Based on Three-Photon Coherent Population Trapping, by C. Champenois, pages 1-4 terahertz signals can be propagated over long distances, the useful information being carried by the relative frequency of three optical photons. With the use of these atoms, Ca+, Sr+, Ba+, Hg+, made in a narrow dark wire line cladded onto the metal box springs in FIG. 1, #6, on the north side of every metal box springs wire line whose frequency lies in the terahertz range. This is the electric-dipole forbidden line as shown in FIG. 9, # 116 and FIG. 10, #126, interdigital electrodes oval loop quantum gravity process. This dual deck layering is where the transition stands in the optical domain in this magnetic-dipole transition which comes from the second-order Doppler shift, the quadruple shift, and the Zeeman shift because of the play performance reaction on size, distance and thickness of the metamaterials and superconductors point placement that is exposed to the electrical current and onto the Hertzian sine cosine box springs for the contraction of both lower and upper decks of this antenna in order to hold and process the light signal. Such a level of stability is being claimed. The chemically changing frequency of one packet will be the sum and that of the other packet will be the difference of the frequencies of intersecting beams shown in FIG. 10. On the south side of the line Hertzian sine cosine wave in FIG. 2, #40, FIG. 3, #57, FIG. 4, #82, FIG. 5, #89, FIG. 9, #113, and FIG. 10, interdigital electrodes oval loop quantum gravity line system and #126 is an electrical circuit wire that connects and runs on to the lower deck of the sandwich antenna loop which runs through the center of the connective loop quantum gravity structure and is called memristor resistors with memory. The memristor resistor is a part of the usual reconfiguring of the backward folding characteristics which resistance increases as current flows through in one direction and decreases when the current is reversed. If the current is cut off the memristor line passing through it completes its connection with or without current. The reason for this is that voltage exerts a slight chemical tracing force, subtly redistributing the atoms in the crystal structure of a semi-conductor altering its degree of resistance in the quantum oval loop region of the metal box springs continuous coupling because of the scaled down in size and distance design. These mencapacitors and meninductors passive components with memory between charged, current, and voltage produces the necessary flux at conjunction of the mencapacitors and meninductors, as stated in Jonathon Keats' book Virtual Words, page 49, and is illustrated in this invention in FIG. 4, #82, FIG. 5, #89, #87, FIG. 9, #113, #116, FIG. 10, 122. This memristive phenomenon is also described in Nature magazine, Vol. 464, 8 Apr. 2010, pages 837-876, article concerning ‘ Memristive’ switches enable ‘stateful’ logic operations via material implication, by Julien Borghetti, which these vertical line wave-wires are called Memristor arrays comprise one layer of platinum wires that sandwiches a 50 nm thick side active later of TiO2, as shown in FIG. 4, #82 and FIG. 9, #116 that crosses over in FIG. 10 and connects to # 123. On the north side of the vertical waveguide, as shown in drawing FIG. 2 #40, #39, #38, # 52, and all north side of the waves is a large arrays of antennas in the lower deck of this system as stated in Physical Review Letters, Vol. 103, 18 Dec. 2009, Efficient Nonlinear Light Emission of Single Gold Optical Antennas Driven by Few-Cycle Near-Infrared Pulses by T. Hanke. The metal horizontal and vertical nano-antennas have been demonstrated to work as optical analogues in conjunction with the metal box springs waveguides to connect to the light emitters of the connective oval loop quantum gravity coupling constance connected to both the lower and upper deck compression in order to hold and trap the incoming signal attached to the metal box springs as shown in FIG. 1, #7, #8, FIG. 9, #118, #116, #117, FIG. 10, # 121, #123, #124. The quantum oval loops are elliptically shaped structures which are fabricated via electron beam lithography on fused silica substrate. The thicknesses of the gold film chromium adhesion layer and dielectric substrate amount to 40 nmx2 nm and 170 um thick. These quantum oval loops are electrically compressed and connect the frequencies to both decks and controlled by metamaterial sectorial zoning as a substrate shown in FIG. 3, #66, #70, as also stated in Physical Review Letters, Vol. 104, 8 Jan. 2010, pages 1-2, Long-Wavelength Optical Properties of a Plasmonic Crystal by Cheng-ping Huang. Both the upper deck and lower deck plates have a layer of plasmonic crystal which is composed of gold nano-rod-shaped particles because of the strong coupling between the incident light of the upper deck and now the lower deck of the metal box springs. By the use of this plasmonic photonic crystal gold nano-rods to produce a photonic stop band opens up this new metal box springs way of manipulating the motion of photons This is the strong couplings between the photons and lattices vibrations as shown in FIG. 10, 119 through # 126, interdigital electrodes oval loop quantum gravity process. The surface plate system is a set of parallel and horizontal design waveguide structures that form an X axis of energy control. The refluxtivity energy emission is collected in this transmission geometry with an electro-optic lens on the substrate surface of the crystal plate, as shown in FIG. 3, #58. In the article The Confinement of Quarts by Yoichiro Nambu in Scientific American, page 56, in the diagrams depicting arrows, the first arrow is a low energy line arrow which is also shown in the invention in FIG. 1, # 27. In the same article the next arrow depicts a medium energy for the light path, as shown in the invention in FIG. 1, # 11 through #33, from right to left. The next phase mode of high energy arrow is depicted in FIG. 4 under the reversing reflux fold in #79 and #76. The next geometric energy mode is infrared containment, depicted in FIG. 4, # 80 up and #84 down, the last energy mode of ultraviolet expanse, as shown in FIG. 9, #113, # 114, #116. This electromagnetic spectrum range produced on the layered wire complex oxide parallel fringe coatings of the metal box springs and crystal superconducting metamaterials substrate provides the transformation waveguides for the wavelengths in meters from 10−15, 10−20, to 10 −10, 10−12 which goes to the frequency in hertz from ultraviolet through infrared at a frequencies of 10 −15 to 1 to 105 range that encompasses microwaves, radar, TV, FM radio and all radio waves which will encompass the forbidden zone. Even though these specific spectral ranges are a positional contradiction, this metal box springs will accommodate this full range of electromagnetic spectrum because of the use of manmade metamaterials and superconductor and complex oxide fringe design placement. These quantum electrical vertical loops and quantum oval loops connective wave circuits are quasi-direct-current waveguides. In the book Almost All about Waves by John R. Pierce, pages 129-130, the chapter on Polarizations support the concept of the metal box springs vibration being controlled in both north and south, east and west and in a polarized vertical wave direction. When this antenna is used as a transmitting antenna, it may produce a wave whose strength varies over the aperture. When this wave glides along the metal box springs substrate, it has an effective area as shown in FIG. 1, #11 through #33 which is the substrate platform in the same area of this metal box springs antenna that utilized both receiving and transmitting antennas that has the same effective process. As shown in Almost All About Waves by John R. Pierce, page 173, Antennas and Diffraction, Diagram 16.8, depicts the geometrical aperture or area of transmitting antenna process. This light-sensitive transparent X-design opening or Saint Andrew's cross opening between the wire wave guide and the travel light signal that passes in between the design structure, as depicted in FIG. 9, #118, center oval loop quantum gravity that connects the two waves from #115 to #117. In the quantum oval loop gravity design, FIG. 10, that is connected to the light-sensitive transparent Saint Andrew's cross linear energy transmission field over the constant repetitive aperture of the metal box spring that is repeated by complex oxides throughout the entire antenna directivity diagram grid, as shown in FIG. 1 of this invention. Also, as support in Physical Review Letters, Vol. 99, 14 Dec. 2007, pages 1-4, Cerenkov-Vavilov Formulation of X Waves, the metal box springs design is establishing a connection between the X waves and the well-studied physics of observed superluminal phenomena such a Cherenkov-Vavilov radiation in the electromagnetic context or supersonic effects such as bow waves in an acoustic context. In this invention these X waves become a phase-folding process. The first quadrant high frequency in the same article on page 4, FIG. 3, shows a Saint Andrew's cross, a standing X wave field and the electromagnetic consequences of this motion concerning Maxwell's equations are therefore conclusive proof that establishes the metal box springs design that will produce selective frequency bandwidths that flow into the Hertzian parallel complex oxide stripes cladded to superconductors and to be held to sectorial zoning of manmade metamaterial boundary layers that hold and fold and set up for bump the light signals between the spectral zones. This energy cross movement is produced when the incorporating beam propagates on the surface and downward into the center of gravity which is called the quantum oval loop of this traveling coupling constance design, as shown in FIG. 1, #29, and FIG. 10, zero order rediffracted beam process electrode and the incoming vertical light signal being flopped or collapsed on to its waveguide side horizontally oriented Hertzian metal box springs, as shown in FIG. 2, #36 This vertical beam and Saint Andrew's cross are the first connecting to the incoming crystal surface plate and then the two outgoing reflective beams—one propagating upward and the other downward into the center of gravity in this design device antenna. Both incoming and outgoing beams collapse according to the horizontal metal box springs design horizontally in repetitively complex oxide layerings molded in the same direction as the incorporating beam with the higher absolute value of its frequency. The frequencies of the two incoming beams have the same frequency but propagate in opposite directions, as shown in FIG. 4, #80, #84 and #82. As illustrated in Principles of Terahertz Science and Technology by Yun-Shik Lee, page 106, Lithium niobate, LiNbO 3, will be used in this invention because of its unique properties such as its high optical transparency over the broad spectral range of 350-5200 nm and its strong optical nonlinearity, ferroelectricity and piezoelectricity properties and large electro-optical coefficient d33=27 pm/V, as shown in FIG. 1, # 11-#33, used as a platform substrate below the metal box springs which creates the negative composite repetitive form. The Terahertz Science and Technology book, on page 141, section 4.7, shows the backward folding wave oscillators in which the metal box springs uses this same process where the electrons are slowed down by the metal frame of the box springs edge where the 36 empty holes and 36 hooks that connect the metal box springs structure is connected to the Saint Andrew's cross which controls the light-sensitive kinetic energy of the electrons around the metal rectangle frame. These 36 empty holes are toroidal dipolar magnetic holes used to produce toroidal rotation symmetry to rotate polarization of the incoming light signal, coupling constance connection of negative index of refraction, interacting between electrical currents producing toroidal monopoles in the 36 empty holes on the frame of the metal box springs grid that now is connected to and by the spring hooks. This was reported in the Science article, “Toroidal Dipolar Response in a Metamaterial by T. Kaelberer, 10 Dec. 2010, Vol. 330, pages 1510-1512. The article on page 1510 specifically depicts the empty hole in FIGS. 1, A, B and C. This dual movement of upper to lower deck travels right to left and then left to right forming an axis of a Saint Andrew's cross which produces the surface energy for the first folding refluxtivity process. This folding phase in this rectangle controls the waves that move in opposite directions that are folded also at the same time west to east at the inner rectangle edge of the box springs antenna located in FIG. 1, #27. This continuous coupling constance of gravity's connection to the south magnetic pole on the west side and the north magnetic pole on the east side which creates the flipping phase of the backward folding under movement down into the lower deck crystal layering plate is the second folding of the light signal. This becomes the coupling constance folding phase of the electromagnetic field which is made of a manmade metamaterial that creates a sectorial zoning that produces an unusual quantum Hall-like phenomenon, as stated in Nature, Vol. 452, 24 Apr. 2008, pages 970-974, A topological Dirac Insulator in a Quantum Spin Hall Phase by D. Hsieh. This manmade metamaterial mentioned in both articles has a zero external magnetic field made of BiFeO3 which is used in this invention and also is explained in Physics Today, October 2010, Multiferroics: past, present, and future by Nicola A. Spaldin, pages 38-43. The BiFeO3 mention in the articles cited above is being used in this invention for two or more transition transparent metal cations, usually 3-D, and oxygenated because these complex oxides are chemically inert and nontoxic and because the elements are abundant that produce strong polarizability. These material elements are desirable properties in ferroelectronics and also desirable in this invention, as shown in FIG. 3, top plate, #64. In these ferroelectric materials, as mentioned in article in Physical Review Letters, Vol. 103, 18 Dec. 2009, pages 1-4, in Selected for a Viewpoint in Physics Electrical Field Switching of the Magnetic Anisotropy of a Ferromagnetic Layer Exchange Coupled to the Multiferroic Compound of BiFO3 by D. Lebeugle, this magnetic-electric effect links the antiferromagnetic spin to the local polarization in BiFeO3 of the Fe3+, and more specifically as stated in Science, Vol. 329, 2 Jul. 2010, pages 61-64, as stated on page 63, explains the results, that the dopants are nearly in the 3+ valence state and always obtain the high-spin state because of the large Hund's rule coupling of the 3-D transition metal ions. This will directly lead to the insulating state of Fe-doped samples, because the Fe 3+ has five 3-D electrons, favoring the 5 up and 0 down configuration in a high spin state and resulting in a gap between the majority and minority spins as shown in the invention in FIG. 1, wire line #6 to # 24, #16 to #30, #18 to # 32. Both articles cited above and below, namely, the two Physical Review Letters. Vol. 102, 6 Feb. 2009, the Dynamics of Multiferroic Domain Wall in Spin-cloidal Ferroelectric DyMnO3 by F. Kagawa and Physical Review Letters, Vol. 103, 13 Nov. 2009, The Nature of the Magnetic Order and Origin of Induced Ferroelectricity in TbMnO3 by S. B. Wilkins support use of these metamaterials and complex oxides. In this invention these complex oxides formulas, mentioned above, are shown in FIG. 1 's repetitive Hertzian sine cosine wave line wire guide made of DyMnO3, as shown in line wire guide #17 and # 19 and alternatingly cladded together in this border TbMnO 3, YMnO3 and CaMnO3 as cladded layerings alongside each repetitive Hertzian sine cosine metal box springs wire, as shown in line wave wire guide #14. These complex oxides create a parallel striped layering fringe effect which is composed of these multiple mixture placements of multiple cladded stripes of superconductors oxide design cladded alongside of the metal box springs that is controlled and initiate through the use of electrical current that effects all of the stripes that are placed alongside of each other and the incoming incident signal radiation forms a chemical reaction producing a different process width in the bandwidth creating multiple spectrum frequencies that react to the electro-magnetism chemical formula of the combined complex oxides. In this striped parallel design of the metal box springs are multiferroics, in which electric and magnetic orders co-exist between the sectorial zoning areas of the metamaterial holding phases. These gigantic magnetic electric dielectric phases layerings of metamaterials will be 1 nm in size cladded on the north side of the wire metal box spring as shown in FIG. 1, #11 and # 23. In conventional ferromagnetic or ferroelectric materials, the motion of the domain walls are key to the directional functions of holding and folding; it provides a huge-response, i.e., magnetic or dielectric susceptibility as well as low field control of the multiferroic, i.e., concurrently anti-ferromagnetic and ferroelectric domain walls in multiferroics of large magnetic-electric coupling in these metamaterial substrate which is placed below the path of the multiple striped Hertzian sine cosine waves wave line complex oxide waveguide selectors. The concept stripes used in this invention is conveyed in Letters, Nature, 2 Dec. 2010, Vol. 468, pages 677-680, Fluctuating stripes at the onset of the pseudogap in the high-Tc superconductor Bi2Sr2CaCu2O 8+x by Colin V. Parker. The analysis of these stripes establishes the phase-coherent properties that produce the design metal box springs layering cladding complex oxides of the waveguides for the correct modulations behavior that produces the multiple spectrum frequency position of the light signal production. Also as stated in Physical Review Letters, Vol. 103, 13 Nov. 2009, pages 1-4, A Ferroelectric with Multiple Inhomogeneties by Desheng Fu, in these metamaterial sectorial zoning areas, as shown in FIG. 2, # 41, #49 this metamaterial component plate is composed of Relaxor Pb, Mg 1/3Nb 2/3, O3 that is in combination layering with FIG. 1, #17 #19 combination with Magnesium+ that forms a giant dialectic and electromechanical responses in relaxors or as a colossal magnetoresistance. This giant dialectic as shown in FIG. 1 # 15 to #28 and line arrow #27 to the center of gravity will be made of Sr3Cr2O8. As stated in Physical Review Letters 103, 13 Nov. 2009, Field-induced Bose-Einstein Condensation of Triplons up to 8K in Sr3Cr 2O8 these optical lattices are used as superconductors in this center of gravity process design. In FIG. 1, #1 the top square frame is made of LuFe2O4 that produces a giant magnetic coupling frame between the upper deck and lower deck in FIG. 3 #56 and #66. FIG. 1 # 11 to #23 is made of Na24Si-136 which is stated in Physical Review Letters, Vol. 104, 8 Jan. 2010, pages 1-4, which are intermetallic clathrates in the north position frame of this design square. This thin calcite opal gem layering plate which separates white light into color spectral components is made of a calcite crystal prism CaCo3K, NaAl, Fe, Li, Mg, Mn3 Al, Cr, Fe, V6BO33Si, Al, B6O18 OH, F4 layering. This line of calcite opal crystal prism is a frequency standard for timing devices, radio transmitters and receivers that are piezoelectric in design in material development that is shown in FIG. 3, plate #58. According to Physical Review Letters, 100, 11 Apr. 2008, pages 1-4, Hierarchical Assembly of Nano-particle Superstructures from Block Copolymer-Nano-particle Composites by Huiman Kang, these nano-particles can now be synthesized with remarkable control over shape, composition, and surface functionality leading to new metamaterials with well-defined properties. This is the new application for the metal box springs refluxtivity development of magnetic, electrical, and optical properties in a nano metamaterial sectorial zoning in the scale thickness of 20-40 nm which will provide an unprecedented level of influence over the local distribution of nano-particles within the arrays at the scale of a few nanometers over this vast landscape of 20 mmx30 mm rectangle square patterned surface aperture of this antenna that will give a first order particle to the metal box springs stripes interpolation scheme of end-to-end, north-to-south scale model of Einstein's gravitational model on a miniature universe scale. The general approach to fabricating nano-particle arrays non-regular device oriented structures of annealed nano-composite metamaterials and the corresponding nano-particle arrays consists of an assembly repetition stripes alongside of the metal box springs waveguide made of a ferromagnetic and antiferromagnetic chemical nano-pattern consisting of wave bends of 90°. The next plate layering is 0.01 mm thick synthetic photonic band-gap material made of an opal gem developed by Dr. Alexander Bulatov, Russian Academy of Sciences, Chemogolovka in order to channel the specific wave lengths of refluxtivity light by diffraction, as shown in FIG. 3, #59. As stated in Physical Review Letters 102, 15 May 2009, Anomalous Refraction of Light colors by Metamaterial Prism by Mario G. Silveirinha, the top plate of this antennae, as shown in FIG. 3, #59, will be a prism-opal combination with calcite layered on top of the crystal gem that separates white light into spectral components in such a manner that the colors associated with the shorter wavelengths are more refracted than the colors associated with longer wavelengths according to the connective coupling constance of the color light radiating through the transparency of the crystal connecting onto the metal box springs complex oxide waveguide design. Physical Review E, 74, 2006, “Broadband diffraction management and self-collimation of white light in photonic lattices” by Ivan L. Garanovich, gives the reason for the calcite and the gemlike quality prism that the calcite-opal is being used on the top plate. This calcite combination of opal gemlike prism crystal produces the correct separations of the white light and super continuum separation of the double prismatic multicolor Talbot effect that runs north to south in FIG. 1. The calcite double refractive line will move from north to south as an optical separator that governs the scattering of waves from modulations of refractive indexes and their subsequent interference. The spatial beam diffraction also depends on the wavelength of the incoming beams self-collimation which is being restrictive to a spectral range according to the double refractive image line in the calcite crystal. This wavelength-independent diffraction management is now a very broad frequency range covering up to 50% of the central frequency as shown in FIG. 1, #11 through #33 substrate plate that is placed below the metal box springs. The same article, Garanovich, et al., on page 2 depicts specifically the metal box springs broadband waveguide array that institutes the connective complex oxides to each broadband diffraction management is stated in this invention, as shown in FIG. 1, #11 through # 33 substrate. This repetitive bending waveguide coupled with bending complex oxides stripes create the higher connective bands associated with broadband self-collimation. This metal box springs invention hybrid structure provides a dynamic improvement in band width for self-collimation effect of this new refluxtivity trapping, holding and folding of the incoming and outgoing wave frequency along the sectorial zoning metamaterial process. Also the management that is being considered in this metal box springs that separates white light into multicolored Talbot effect allows this device to massively manipulate billions of white light into color pattern signals on the entire aperture surface structure of this antennae. This will optimize the entire 20 mmx30 mm surface of the logical arrangement to all incoming incident light signal arrays, according to the new superconductors and metamaterial substrates in this design. The lossless metamaterial-calcite-opal prism with a suitable microstructure will enable a broadband cavity mode regime of anomalous dispersion, where the spectral components of light are separated in an unconventional way, so that “violet light” is less refracted than “red light” which makes this design on a microstructure and will make this multiple dual-deck cavity mode process a reality. According to Infinite Energy, Issue 71, 2007, page 20, “The refractive index for longer wavelengths (red) as lower than those for shorter wavelengths (violet). This results in a greater angle of refraction for the longer wavelengths than for the shorter wavelengths. This phenomenon is quantified as the index of refraction; the fact that refractive indices differ for each wavelength of light demonstrates that they propagate through the prism at a different velocity.” The Physical Review Letters, Vol. 103, 2 Oct. 2009, pages 1-4, in the article “Dynamical Casimir Effect in a Superconducting Coplanar Waveguide” by J. R. Johansson, article support the relationship to the metal box springs design created the same Casimir effect that is in the coplanar waveguide that is listed in this article. It concerns two parallel mirrors in empty space are attracted to each other due to the vacuum fluctuations of the electromagnetic fields because of the different mode density inside compared to the outside of the mirrors. According to the Physics of Waves by William C. Elmore, on page 67, concerning the “Interference Phenomena with Plane Traveling Waves,” that this “sending plane sinusoidal waves toward a rigid straight boundary along which the wave amplitude is necessarily zero at all times.” This diagram on page 67 FIG. 2.4.1 shows the wire line source as being image of the other dual stack arrangement in the rigid boundary and the boundary as being a plane mirror decks arranged in the lower deck, as shown in FIG. 2, #42 and #43 . This striking effect of quantum electrodynamics was predicted by Casimir in 1948, and is now used in the metal box springs design layering as shown in FIG. 1, #1 and FIG. 2, which is the lower case wave line electrical circuits is in combination with FIG. 3 drawing showing the total combination of the two designs layered together in FIG. 3 which is a sandwiching of the two layers in between a liquid crystal made of a fiber crystal salts, as stated in “Casimir force, antennas, and salt water.” As famously predicted by Hendrik Casimir in 1948, parallel conductors in a vacuum will attract each other because the conductors impose boundary conditions that affect the vacuum energy of the electromagnetic field—see the article by Steve Lamoreaux in Physics Today, February 2007, page 40). In general the Casimir force depends on the shape of the conductors. Now a team at MIT has shown how tabletop measurements' might provide the key information needed for the general calculation. The Casimir force may be expressed as an integral over frequency, ω, of correlation functions that involve electric and magnetic field combinations associated with gravity that this quantum oval loop brings the three-field processes together. The key observation made by the MIT team is that their mathematical expressions always involve ω in the combination Єω2, where E is the permittivity. Thus, the researchers predict a force integral with real vacuum permittivity and complex contour can be calculated from a tractable number of antenna measurements made at ω in a medium of complex permittivity—for example, salt water, as supported by A. W. Rodriguex, et al., Proc. Natl. Acad. Sci. US, 107, 9531, 2010. In this dual metal box springs as stated in Physical Review Letters, Vol. 104, 8 Jan. 2010, pages 1-4, Novel Defect Structures in a Strongly Confined Liquid-Crystalline Blue Phase by Jun-ichi Fukuda, that in this invention will be using the blue phase in chiral ferromagnets as MnSi liquid crystal and air interface structure instead of a liquid salt. The reason for the blue phase is because of the double twist cylinders called skymrions and it satisfies the two-layered dimensional electron systems in this new antenna dual-deck system. This is proven by the diagrams of this article on page 2, FIG. 1, showing the design formations that are identical to the metal box springs fourfold symmetry axis in a confined vacuum system. As shown in FIG. 1, #6, #13 to #25 is made of aluminum+base crystal line wire superconductor. The article in Physical Review Letters, Vol. 100, 4 Apr. 2008, pages, 1-4, Measurement of Terahertz Conductivity of Intense Laser-Heated Dense Aluminum Plasma, by K. Y. Kim, states that the Aluminum+ creates the Drude model for warm dense matter, ion-ion interaction ultrafast terahertz frequency near zero frequency conductivity. As indicated in Physical Review Letters, Vol. 102, 27 Mar. 2009, Optical Nonlocalities and Additional Waves in Epsilon-Near Zero Metamaterials by R. J. Pollard and Victor A. Podolskiy pages 1-4, at near-zero regime such as this metal box springs being presented in this invention uses manmade metamaterials, optical composites with structural units smaller than the wavelength in this multi-scale light coupling antenna which uses the epsilon-near-zero metamaterials in which components of the real part of the dielectric permittivity becomes vanishingly small. This nonlocality accompanied by excitation of the additional polarized electromagnetic wave in this sectorial zoning of metamaterial systems will be the correct material function for this new side band horizontal metal box springs refluxtivity design application. In conjunction both the forgoing and the following article, Physical Review Letters, 100, 30 May 2008, by J. Nagel, Observation of the Negative Absolute Resistance in a Josephson Junction, pages 1-4, motion against the static force is termed negative absolute mobility or negative absolute resistance because of the nonlinear system's in this invention produces a negative differential resistance and also negative absolute resistance of Nb—Al—Al0xNb complex oxides which will produce frequencies in the Ghz range, as shown in FIG. 1, #6 cladded on all north side repetitively of all the metal box springs Hertzian waveguides. In FIG. 1, #19 to #33 on the south end of this antenna, the concepts are stated in Nature, Vol. 45, 19 Feb. 2009, China's Crystal Cryanoski, this crystal is nonlinear, barium borate BaB2O4 is to generate zero to edge contact as shown in FIG. 1, #20, controls wavelengths of 200 nanometers in combination with the Mg+ substrate at the south end of this nano-framed antenna design. Each incident signal large wave packet compacts into and unto the antenna system's edge which compliments the energy system radiating on the surface plate that is folded under in the next surface plate edge. This is called refluxtivity folding. This refluxtivity phase movement is holding the frequencies and are being bumped and moved into the folding edge position in a reverse movement action into the electromagnetic metamaterial sectorial zoning cavity of this antenna. This incoherent incoming signal wave packet travels along the complex oxide stripes of the box springs design, using the complexity sizes and widths to the fullest extent of the traveling distance of each light bandwidth wave through the use of refluxtivity latching dragging and folding that holds in place and makes a manmade metamaterial reconnection to the integrated line superconductor design and surrounding space in the sectorial zoning lines boundaries for permanently holding the incoming signal which now will not break from the system device to which this antenna is attached. This rectangle surface mmx30 mm aperture and the metal box springs design receives a full incoming signal bounce of gravity into the electromagnetic oval loop quantum gravity design that induces a larger connection to the metal box springs broadband cavity mode product. The metal box springs design is flat and collapses the incoming incident wave that connects to the surface structure that has a very low electrical current connection. This incoming incident wave passes through this transparent crystal and connects to vertical, perpendicular, and horizontal design coupling constance and on to the superconducting parallel complex oxide stripe fringes and down through to the sectorial zoning reconnection to a manmade metamaterial layering to reconnect for holding and folding process. The use of anti-ferromagnetic crystal structure plates produces the holding in a constant forward and backward refluxtivity coupling phase folding reception of all incoming incoherent signals that are passing through the double electromagnetic gravity quantum oval loop based on a universal space and time design described by Einstein's Special Relativity Theory of expansion, contraction and collapsing. The Hertzian sine cosine cladded stripes of complex oxides attached to the metal box springs fabric Hertzian fringe line wires are on a nano-scale magnetic and antimagnetic superconducting material that stretches over a vast nano-micro-macro distance of this rectangle square that is 20 mmx30 mm and is 1 mm thick and is the perfect depth of this dual deck design that holds the invisible gravity force connection between the contradiction of movement versus broadband cavity mode distance of the incoming electromagnetic wave signal that collapses and compresses onto a nano-thickness of the metal box springs design. The use of manmade metamaterial sectorial zoning compresses the electromagnetic incoming light refraction reconnection that enables the incoherent light waves to expand and bounce naturally onto the electro-magnetically warped box springs' frame that receives and controls the vibration by strong pressure compression and the release expansion in combination of hooking the incoming light signal which reacts on to the complex oxide chemical striped formulation cladded to the metal box springs. The gravity movement pushes on the bed fabric and connects to the electromagnetic metal box springs design of the quantum oval loop which is the center of gravity position located in FIG. 1, # 29 and all coupling constance 66 loops, 36 holes and 36 hooks that simultaneously hooks and disseminates the incoherent multiple signals that are entangled together by electromagnetic gravity process of refluxtivity and relativity process design. The metal box springs design is confirmed in Physical Review Letters, 99, 28 Sep. 2007, specifically showing the light wave guide which is the metal box springs design line wire structure. This is seen through a scanning electron micrograph around 100 nm scale bar of In As dot bridges which confirms the line design of a metal box springs that will be used in this invention. As discussed in this Physical Review Letters, 18 Nov. 2005, Vol. 95, #26, it is conclusively proven that the metal box springs design invention will produce the correct spatial dimension and complex proportional sizes in a scale position of singularity contradiction process in order to produce the necessary broadband cavity mode process that takes in the contradictions of size that ranges from the forbidden frequencies areas on the light spectrum that will encompass atto-10− 18, nano 10−9, micro 10−6, milli-10−3, and mega 106, megawatt, giga 10 −9, gigahertza, terahertz 10−12. These ranges in the spectrum will encompass the long and short milla microns of bandwidth cavity mode transmission operation. As stated in article Physical Review Letters, Vol. 101, 19 Dec. 2008, Metamaterial Analog of Electromagnetically Induced Transparency by N. Papasimakis and in this invention, FIG. 1, #1 depicts the outer square line of the frame of the antenna which is made of compressed NbGe. This outer frame has the ability to carry high current vibration in the present of high magnetic fields which is 100 nano-meters thick and 100 nano-meters wide, housed in a square form frame. This metal frame is holding the metal box springs design grid together, as shown in FIG. 1, #1. In this frame there are connective 36 empty holes drilled around the square form frame which amount to 36 empty holes and 36 hooks. The center hole ring is made of NbTiTc that activates the Maxwellian electromagnetic unit of magnetic reflux on to the connective spring, as shown in FIG. 1, #2. The creates a magnetic flux which, linking a circuit of one turn fold, produces in it an electromotive force of 1 ab V as it is reduced to zero in 1 then 1 Maxwell=10-8 weber electrical units and standards which is at 10-9 nano-size as stated above and shown in FIG. 1, #2, FIG. 4, #72, #73 and #75, FIG. 5, #94, #95, # 96, #98, FIG. 6, #105, #106. This design produces an expanding and contracting that will facilitate all incoming signals and will hold all frequencies in place controlled by electro-magnetic refluxtivity reversing folding phrase process. FIG. 1, #3, depicts the spring coil connection between the 36 empty holes and oval loop quantum gravity in #4 on to #5 box springs, also #6, and oval loop quantum gravity connectors, #7 and # 8, are the multiple overlapping hook loop quantum gravity ring connections from the empty hole at #9 which is described in detailed from FIG. 4, #75, FIG. 5, #98, #97, #96, #94, FIGS. 6, 7, 8, #96, #100, #102, # 107, #109, #110, #108, # 111, FIGS. 9 and 10, which show the coupling constance overview of all the design control manipulators of light transition process in the retrodiction refluxtivity in this trapping wave guide design device controlling process. This quantum oval loop center of gravity design is the connective link of the coupling constance conductivity of the lower deck electromagnetically coupling and controlling of the Hertzian striped parallel complex oxide fringes cladded to the superconductor line bandwidth. This complex oxide design material connects parallel to the ten empty holes located in the north with hooks on the top of square and ten empty holes with hooks on the south of the square, making a total of 20 empty holes with 20 hooks, as shown in FIG. 1, #2 and #20, running consecutively across the edge of the north and south square line. In FIG. 1, #9 and #27, the empty holes run consecutively on the east to west side of the square rim which total 16 empty holes with 16 hooks that connect the metal box springs horizontally which become the impedance coupler of empty holes which enter the asymmetric phase coupler ports areas which are placed on both east right and left west sides of the square of this metamaterial design. The east and west side hook to eight empty holes on the right and eight holes on the left side of the square structure frame. As stated in Physical Review Letters, Vol. 102, 30 Jan. 2009, Proposed for a Mesoscopic Optical Berry-Phase Interferometer by I. A. Shelykh, that these empty holes with hooks are a novel way to produce spin-optronic device based on the interference of polaritonic wave traveling in opposite direction and folding under and through the holes and hooks splitting on the Zeeman effect which are used to control the output of its peculiar orientation of its electro-magnetic field for polaritons where the spins of single particles are precisely manipulated and controlled as a spin transistor. As depicted on page 2 of the Shelykh, et al., article, and as maintained in this invention, this hole and hook microcavity waveguide is located in this invention design, as shown in FIG. 1, #2, hole north rail of ten empty holes transistors with splitting Zeeman effect hooks attached clockwise, ten empty holes on the south side of this rail which are transistors with hooks that are anticlockwise and with eight empty holes on the west rail side with hooks. These double dome holes are magnetic magnets for up and down folding manipulation of the light wave port holes, as shown in FIG. 1, #27 of eight empty holes and eight empty hooks on the east rail side which are made of antiferromagnetic properties for the first incoming incident wave signal for refluxtivity folding under and on to the first layering deck plate, as shown in FIG. 3, #58 and FIG. 2 vertical, #36. FIG. 1, #8 and # 9, specifically, are isolated conventional points of backward-wave couplers on the right side of the square which are through the two empty port holes and hooks and on the left side are of hook and empty holes that are beginning forward-wave coupler input port. This is depicted in Metamaterials by Richard W. Ziolkowski, pages 198 and 199, metamaterials couplers in FIG. 7.7. This book's article explains the drawing configurations, as shown in FIG. 4, # 73, #71, #72, FIG. 5, #90, # 88, #89, #87, #86, and FIG. 10, which describes multiple parallel complex oxide stripes that produce interdigital electrodes on all of the metal box springs design waveguide and the coupling constance of quantum oval loop full field unified design connection to the gravity, #123. The above descriptions of the complex oxide stripes waveguides creates order out of this entanglement that will conserve the energy and coherent process of the entanglement of the enlargement of the waves multiple size of each broadband cavity mode within this design counterpuntal counterparts of the metal box springs. Metamaterials by Richard W. Ziolkowski, page 153, describes that Broadband Wilkinson Balum Using Microstrip Metamaterial boundary separation Lines which are used in this invention which is claiming that there are 18 wave guide horizontal and perpendicular parallel metal box springs stationary bandwidths in this two-layered antenna input port that are closely spaced on a nano-size development in order to create low-pass, high-pass output lines which are employed in this new metal box springs quantum oval loop design, as shown in FIG. 3, #66-#58=9 lines=x2 side 18. The pertinent parameters for each metal box springs wave guides and parallel Hertzian complex oxides bends at a −90° on the line wire and cladded alongside the metal box springs at a +90° waveguides Hertzian complex oxides is calculated in this metal box springs design shape of the phase responses to the design multi layerings of the +900 and −90° wire lines that match the 180° phase folding and Saint Andrews's cross gliding across the surface that regulates the incoming large bandwidth cavity mode. This will match the phase response of the −90° of the wave line with that of +900 multiple oxide stripes lines and therefore create a broadband cavity mode waveguides from an optical ferromagnetic superconducting differential output and input phase in the wideband peaks and collective valleys of their phase characteristics which will be equal to the design frequency structure waveguide laid out in this controlling metal box springs design. Each segment metamaterial sectorial zoning substrate does radiate and operate the inner reflective region line boundaries of the wave line which becomes a controlled circuit for the transparent light signal to pass through the superconductor stripes and down onto the substrate, as shown in FIG. 1, #11-#33, FIG. 4, #79, FIG. 5, #91, FIG. 6, #105 and #104, FIG. 8, #110, FIG. 9, #116 and FIG. 10 full field interdigital electrodes quantum oval loop gravity design, as shown in #122. This works well because it has to do with mutable miniaturized sizes in the design itself and the spatial sectorial zoning of metamaterials in a nano-micro-macro manmade repositioning in order to get the results necessary in holding and folding the light signal into a permanent position. This is the claim of this invention that it will produce a permanent holding coupling of the incoming light signal as compared to the antennas of today which are only a small aperture in size which creates the breaking effect of the incoming light signal. In this invention the aperture retrieval is 20 mmx30 mm in size which eliminates all the dysfunctions associated with breaking the connection when said device is under a tunnel or in a conflicted electronic area that breaks the incoming signal. This design improvement is the basis of the claims of this invention. The reality level may seem usual because of the use of the term of metal box springs is extenuated to the maximum of what new material research development can produce. Its design process has been proven in all of the advanced visual understandability as depicted in all of the journal articles mentioned in this document.