DISTRIBUTIVE OPTICAL ENERGY SYSTEM

Abstract

A system for generating and transmitting energy including prisms, lenses, mirrors, optical conduits, heat filters, light filters, and electricity filters. The lenses comprise lens systems to capture electromagnetic signals coming from any source of radiant energy. Upon receiving the electromagnetic signals, the lens system multiplies n times the intensity of the signals by a method of infinitesimal folding of signals, a method basically consisting of an overconcentration of signals folding onto themselves multiple times in order to produce substantially concentrated signals and to project the substantially concentrated signals into one single optical cable. These substantially concentrated signals are transmitted long distances as they are reflected through the interior of these optical conduits (in a conceptual manner similar to signal reflection in Tiber optics cables). At the distal ends of the optical cable three filters will extract heat, white light and electricity.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is claims the benefit of U.S. Provisional Patent Application No. 60/728,245, filed Oct. 19, 2005, which is herein incorporated by reference in its entirety.

COPYRIGHT NOTICE

A portion of the disclosure of this patent document contains material that is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure, as it appears in the Patent and Trademark Office patent files or records, but otherwise reserves all copyright rights whatsoever.

FIELD OF THE INVENTION

The invention relates to a distributive optical energy system and method. More specifically, the invention relates to a system for transmitting solar and non-solar energy through one or more conduits of heat-resistance optical cables.

BACKGROUND

It has been known since Einstein's break with classical physics that light travels as both a wave and particle, and that energy is directly proportional to a body's inertia and to the speed of light. It has been also known from his special relativity that the energy of any object can be found by combining its inert with its kinetic energy in an equation with just three parameters: mass, the speed of light and the particle speed. However, to support his theory, Einstein required that time is locked into energy's conservation and conversion principles.

Due to the energy crises and environmental problems, finding alternative energy solutions has been recently put back into the scientific and political discourse. However, at technology level, time is still within the reversibility domain, and energy devices are sill dependent on entropy constancy. Solar energy, for example, has been considered as solely localized, exclusively based on linear models of energy conservation and conversion.

In view of the foregoing, it is believed that a need exists for a system for transmitting electromagnetic radiation that overcomes the aforementioned obstacles, limitations, and deficiencies of currently available energy generating and distributing systems.

SUMMARY OF THE INVENTION

A system for transmitting solar and non-solar energy through one or more conduits of heat-resistance optical cables is disclosed. The system comprises a first mirror-lens system for concentrating scattered electromagnetic solar rays into a focal plane to produce focused rays. A mirror system concentrator concentrates the focused rays by an N factor. The system includes a coupler and an optical cable to align the focused rays into one conduit of an optical cable and generate a complex optical wave. A coupling focusing collimator couples the optical cable to three different filters where the complex wave is converted into focused rays and then into heat, light, and electricity. A heat filter filters the heat. A light filter filters the light. An electricity filter filters the electricity.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 is an illustration of preferred embodiments of a system for generating and transmitting energy in accordance with the present invention.

DETAILED DESCRIPTION

FIG. 1 shows a generator system 200, its first stage composed by objective lenses 220 placed towards luminous, audible and non-audible emitting objects, which emit radiant energy 215 in the form of electromagnetic signals. These electromagnetic signals 215 travel from the said emitting objects in every direction; when the said signals 215 hit the optical collector 210, the reflected signals 216 travel towards the objective lens system 220 from which refracted rays 225 are projected towards a focal plane. A mirror system concentrator (MSC) 230 is placed in axial alignment and at the focal length with the lens system 220. The rays 225 of the lens system 220 (the Zoom lens system) are projected onto the MSC 230, which concentrates the rays n times. In one embodiment, N times preferably vary from tenths to millions. In order terms, by multiplying the rays 225 of the lens system 220 by a factor N, the MSC 230 produces a singular over-concentrated light (SOL) 235. It should be understood, for the purpose of the present description, that the term “light” encompasses all the electromagnetic spectrum, from short waves to cosmic rays. The MSC 230, comprising several mirrors in one embodiment, concentrates rays in order to obtain a maximum absolute intensity, i.e., ray intensity in itself. This maximum of intensity is designated herein as the SOL. The MSC 230 concentrates the incoming rays 225 proportional to the wave/particle concentration area and a pre-defined energy demand. One embodiment comprises 16 mirrors, where the radius of curvatures ranges from 20 mm to 6 mm. This MSC reaches a ten thousand concentration index.

In operation, the resultant concentrated energy 235, i.e., SOL, enters an optical cable 120—which includes one or many heat-resistant optic conduits—through a collimating and coupler system 240. The said collimating system 240 is in axial alignment with the said MSC 230, and the said optical conduits 120 in order to produce parallel rays composing the said SOL 235. Once the SOL 235 enters the conduits 120, the SOL's highly intensified rays reflect in the interior of the optical conduit 120 creating a complex energy wave (CEW) 110. The CEW 110 depends on the diameter and length of the optical conduit 120, on the characteristics of the conduit's surface (such as smoothness and elasticity), on the refractive and reflective indexes of the conduit's core and clad (if applied), on the concentration index of the MSC 230, and on the angle of reflection as the SOL's rays enter the conduit 120.

Preferably, the CEW 110 obeys the following equation:

Z²+C=E,

where E is the complex energy, C is a complex number, and Z is a feed-forwarding variable, which includes E, and is proportional to the wave density. The CEW 110 comprises a light folding process, meaning that its highly concentrated light rays carry heat and white light. At the distal end of the conduit 120, heat, white light, and electricity are filtered out.

At the distal end of the optical cable 110, one or many conduits carrying the CEW 110 are optically coupled, collimated and focused with 1) a heat filter; an iodine compound 350; 2) a light filter: an alum compound 390; and 3) an electricity filter: a thermal pile compound 370. In one embodiment, a filter is an apparatus that extracts a property from a process.

The CEW 110, and its dissipative (chaotic) self-organizing wave structure, allows the use of very low optical cable diameters: varying from a few microns to a few centimetres, depending on each configuration, energy potential source or demand. This fact enables remote installation of these generator units. Note that CEW's self-organizing behaviour happens especially due to the nonlinearities created by collision (intra photon and photon-electron). This loss of momentum dissipates as heat and feeds itself back into the CEW 110, serving as the energy kick that keeps the wave chaotic, therefore self-organizing.

A generator unit 200 (FIG. 1) which includes the ray-capturing system 210/220 (mirror-lens collectors and/or acoustic bowls, and an objective lens compound), the MSC 230, and the coupler 240, can be installed in every source of solar or non-solar radiation. The generator system 200 is divided in two categories: 1) solar radiation which implies the use of solar collectors preferably parabolic or circular mirrors (210) for reflection of solar waves and objective lenses (220) for refraction and focusing of direct solar radiation onto the MSC 230; 2) non-solar radiation which implies the use of optical collectors using a combination of mirrors-acoustic bowls (210) and objective lenses (220) in order to reflect and refract audible (long) and non-audible (short) electromagnetic waves, and to focus them onto the MSC (230). Therefore, any source of electromagnetic radiation, such as human voices, animal or insect noises, friction noises (such as automobile tires on ground), industrial non-audible noises from motors, engines, classrooms, auditoriums, musical instruments, orchestral concerts, ocean waves, and direct/indirect solar radiation, is a potential source of radiant energy. A local station (said generator 200) can be installed in any of these or other sources, then, via one single optical cable, transmit energy to the distal local station (consumer 300) for consumer distribution.

In this case, continuous (day and night) generation of energy can be provided. In one embodiment, a local station includes two types of generators presented: one that captures solar or luminous radiation, and another that captures all other sources of electromagnetic radiation. Therefore, at night-time this latter local station makes use of the non-solar generator to generate energy from all sources of electromagnetic radiation.

In one embodiment, an application of a solar radiation generator unit uses earth's solar energy, which reaches a maximum average of 1 KW/m² (one kilowatt per square meter). One local station using one solar radiation generator unit with a density index of 1×10⁶ (one million) would produce 1×10⁶ KW/m² (one million Kilowatt per square meter). A home in the U.S. requires an average of 30 KW/m². This solar generator unit alone feeds 1×10⁶ KW/m²÷30 KW/M²=30,000 homes.

An application of a non-solar radiation generation unit uses any form of non-solar electromagnetic radiation. Following the logic of the solar generator discussed in the previous example, one local non-solar unit has a density index of 1×10⁶ (one million). A human being's voice in talking mode averages 3×10⁻⁵ Watts while a human being's voice in shouting mode averages 3×10⁻² Watts. These voices can be powered through electronic power amplifiers. In this regard, one person talking alone will theoretically generate through the said non-solar generator unit the following wattage: 3×10⁻⁵ Watts×1×10⁶=30 W. If 1,000 people talk for one hour, they will feed an average home in the U.S. for one hour. Likewise, using the same density index of said generator, one person shouting for an hour would feed one home for one hour: (3×10⁻² Watts×1×10⁶=30 000 W.) From these examples, those skilled in the art can recognize possibilities to use energy from non-solar sources that are immense, and many different embodiments can be used. A city produces an unlimited variety of audible, non-audible, and industrial sources of energy that can be potentialized using the non-solar generator. A rural area has many other potential sources of energy, such as insects, animals, streams, rivers, electricity wiring transmitters, and such, and can include any form of electromagnetic radiation.

In one embodiment, the density index is limited by the quality of the optical cable including its material weight, granularity, elasticity, diameter, heat-resistance factor, and by the quality and heat resistance factors of mirrors and lenses. In one embodiment, the higher the density index, the higher the cable's diameter is increased to improve the cable's, mirror's and glasses' heat-resistance factors. However, the cable's diameter has an exponential relation with the density index, a value that can be optimized for different applications. In one embodiment, the main variables that determine the limits of the density index are: the total reflection factor and the heat-resistant factor of the optical cable; the mirror's planar and spherical reflection index; the lenses refraction indexes; the heat-resistance factor of mirrors and glasses; and the integrity of CEW's dissipative and self-organizing behaviour.

In one embodiment, the use of bio and nanotechnology can aid in obtaining higher density indexes while maintaining a small optical cable diameter so that a higher complex energy keeps its dissipative and self-organizing behaviour (CEW) as it continuously propagates until it reaches the optical cable's distal end (the consumer's end).

In one embodiment, the density index is determined depending on each installation. In operation is a system to capture radiation from a 1 W/m² energy/area source, which is one thousandth the amount of the solar average energy on earth. A single optical conduit of an internal diameter of 10 mm is used. Although the concentrator factor can reach any magnitude, limited by the first law of thermodynamics and adjusted according to each installation, the concentrator factor for the MSC 230 is calculated so that the original 1 m² reference area is reduced to the optical conduit surface area which is π×r²=3.14×5²=78.5 mm². Therefore, the concentrator factor will be 1 m²÷78.5 mm²≈12,740. The average flux at focal point will be 1 W/m²×12,740=12,740 W/m²; and at the conduit's surface area, which is 78.5 mm², the flux will be 1 W/m². Considering an efficiency of 0.9, the real average flux will be 12,740 W/m²×0.9=11,466 W/m². The MSC design is based on concepts known to the art of solar energy collectors, applied to both parabolic and spherical mirrors as well as to lenses, and varies depending on each application. Conceptually, the mathematics of optical collectors design is basically derived from known heat transfer and optical laws, notably: 1) the three modes of heat transfer, namely conduction, convection and radiation; 2) the laws of reflection and refraction relating the interaction between electromagnetic radiation and matter. To calculate the amount of heat at the entrance of the said optical conduit 120, the Stefan-Boltzmann law of radiation is used: H=AeδT⁴ [where H=Radiant Energy in watts; A=Surface Area; e=the emissivity; δ=the Boltzmann constant (5.6699×10⁻⁸ W·m⁻²·K⁻⁴); T=Kelvin Temperature].

In case of a MSC composed of lenses, mirrors, or a combination of both, thermal radiation will be increased and can be calculated using quantum radiation propagation based on two relations: 1) the energy of a photon: E=hv [where v is frequency and h is Planck's constant=6.625×10⁻³⁴ J·s); 2) c=λv=co^a/n (where c=the speed of light; λ=wavelength; v=frequency; co^a=the speed of light in a vacuum; n=index of refraction of the medium.] Note that thermal radiation is usually considered to fall within the band from about 0.1 to 100 μm, whereas solar radiation is concentrated in the wavelength range between 0.1 and 3 μm. The use of spherical mirrors is preferable for having less surface contact, therefore emitting less thermal radiation. Applying the above values in the formula and calculating for T, the temperature at focal point will be:

T=⁴√H/δ

=⁴√11,466 W/m²÷5.6699×10⁻⁸ W·m⁻²·K⁻⁴

T≈671 K≈398 C.

This thermo dense light enters the optical conduit at an angle (less than 45 degrees) such that to balance inner reflection with the conduit's heat resistance. It should be noted that, in order to obey the principle of total reflection through the optical conduit, a core and cladding section (similar to fiber optics but with much higher dimensions) could be applied to the optical conduit's physical structure. As soon as radiant electromagnetic rays enter the cold and reflective surface of a 10 mm inner diameter of the optical conduit, persistent particle interactions cause the optical conduit's internal energy to change; an energy which is limited by the system's thermodynamic limit (the ratio of the total number of particles per total volume). Several physical phenomena will happen at once, but most importantly the rise in temperature will alter the molecular structure of the glass and stimulate electrons to change energy levels, therefore generating more photons. The heat from particle stimulation is transformed in work according to Q=cmΔT [where Q=heat capacity in J/(kg·C°) which depends on the nature of the material (for glass=840); cm=mass in kg; ΔT=the temperature change.] This work feeds back into the electromagnetic radiation. However, because particle collision will be happening in three or more dimensions and in random motion, each particle will change speed and direction of motion, and the interaction photon-electron could generate photons travelling faster than the speed of light. As a photon is absorbed by an electron, the electron transits to a lower energy level, and a new photon is released. This scattering of light could lead the electron to travel backwards in time in order to absorb a photon. A photon, while being generated by a differentiating electron, can also travel backwards in time, changing particle charge and generating an anti-particle. These particles while travelling backwards in time can also collide. When a particle and an anti-particle collide they annihilate each other; however, depending on the amplitude and frequency more than one photon can be released from the particle-anti-particle collision. This phenomenon, according to quantum electrodynamics, illustrates an increase of light intensity and a release of energy that feeds back into the overall electromagnetic wave. The total energy generated will be proportional to the overall glass area of the optical conduit, the quality of the glass, the density index (as discussed previously), and the heat. The total energy E is the sum of the rest energy Eo and the kinetic energy KE, or E=Eo+KE and is based on Einstein's special relativity given by the relation: E=mc²/√1−v²/c² (m=mass; v=particle speed; c=speed of light). From this relation, if, as mentioned above, a particle travels backwards in time (speed higher than the speed of light) then v²/c² will be higher than 1, making √1−v²/c²=a complex number. This new energy equation can be re-written as E=mc²/iy+C (where i=the imaginary part and C=a complex constant). According to Quantum Electrodynamics, the probability of an event is the absolute square of a complex number. Therefore, the probability of the event “particles travelling higher than the speed of light” becomes high in the case in operation. This is one aspect that contributes to the formation of said CEW 110.

Another aspect is the nonlinearity of the glass's surface, which will be even increased by its molecular thermal stress due to heat. As photons and heat stimulate electrons that stimulate anti-particles and other photons and other anti-particles, they vibrate as waves depended on change in momentum, energy and wavelength given by the De Broglie's relation: λ=h/p (λ=particle wavelength; h=Planck's constant; p: the magnitude of the relativistic momentum of the particle). It should be noted that the amplitude for a photon to be emitted by a source varies, in general, with time. As time goes on, the angle of amplitude of a photon to be emitted by a source changes. In the presently described system, the source is white light and its many colors emit photons randomly, making the angle of amplitude change irregularly. Therefore, a photon will change wavelength (therefore color) after being absorbed then generated back as a new photon by an electron. The irregularities of particle wavelength and momentum are other contributions to the creation of CEW.

The second law of thermodynamics states that “heat flows spontaneously from a substance at a higher temperature to a substance at a lower temperature and does not flow spontaneously in the reverse direction.” Therefore, the heat wave flow will seek, in acceleration mode, the optical conduit's distal end. This continual electromagnetic heat-flow moves through the optical conduit and generates a special pattern in which millions of molecules move coherently, a situation that maintains a state of non-equilibrium. Together with the nonlinearity on the glass' surface and the irregularities of particle wavelength and momentum, with time this non-equilibrium state will turn the CEW into a self-organizing wave. Nobel Laureate Ilya Prigogine named this phenomenon “dissipative structure.” According to Prigogine, farther away from equilibrium the fluxes are stronger, entropy production increases, and the system may encounter instabilities leading to new forms of order that move the system farther and farther away from the equilibrium state as these dissipative structures develop into forms of ever-increasing complexity. The high density of particle concentration will allow for the rapidly growth of clusters around more dense areas. These clusters easily move through the expanded (by heat tension) molecules of the glass allowing for the transformation of (inert) energy into active energy as photons stimulate electrons in other regions into the glass' thickness. This process increases the active population growth, i.e., the number of stimulated electrons. The overall energy is given by CEW's relation: Z²+C=E, where E is the complex energy, C a complex number, and Z is a feed-forwarding variable, which includes E, and is proportional to the population density.

Note that external factors, such as gravitation, can be magnified by non equilibrium states which help increase symmetry breaking, contributing to the overall purpose of enhancing active population growth. Furthermore, the optical conduit can be made of organic material so that external factors participate even more dynamically in the increase of population growth (to win particle threshold from inert to active) and the consequent increase of integral energy as well as CEW's travel distance.

A final consideration regarding the building of the MSC 230 relies on the fact that it is common knowledge to anyone familiar in the art of optics applied to solar energy that to capture solar energy both image-forming (IF) and non-imaging forming (NIF) concentrators can be employed. Regarding the IF's, ideal operation can be achieved by the use of spherically symmetric geometry, a dynamically flexible refractive index (for lens-based MSC's), and the use of materials (hybrid organic) with high refractive indexes and close to zero dispersion. Although energy efficiency is much higher in NIF's concentrators, IF's have the advantage of employing materials with much less heat resistance. In compensation, IF's concentrator factors are substantially lower than NIF's. All that is said about IF's and NIF's for capturing solar energy is valid for capturing any source of electromagnetic radiation.

The Heat Filter extracts heat, i.e., it filters out heat from the complex energy wave, CEW. Heat travels in concentrated dissipative form within the CEW; there are many ways to extract this concentrated heat from the CEW. One process is by using an Iodine Composition in solid, liquid or gas form. The solid form, for example, is a prism composed by an iodine solution. In this case, as FIG. 1 shows, CEW 110 signals become the non-scattered highly focused rays 345 after passing through the distributor collimator 320 as they are optically captured by the objective mirror-lens system 340. The said rays 345 hit the iodine prism 350 and only heat comes out because iodine blocks off visual light and allows infra-red to come out; and infra-red light, with wavelengths around 800 nanometers, produces the highest amount of radiant energy. In operation, the optical conduit/s carrying the CEW 110 is optically coupled through coupler 310 to the said distributor collimator 320 optically in alignment with a focusing and collimating system 340, comprised of mirrors and prisms, to capture, align and focus the light rays 325 (the regenerated consumer SOL), so that rays 345 are directly focused onto the said iodine solid, liquid or gas solution 350 from which an over-concentrated infra-red light 355 is filtered out. Placing a bucket of water at the focal point of this ray, the bucket is led to boiling instantly. Placing a solid material like coke, it leads immediately to incandescence. Zinc burns up at the same place, while magnesium ribbon bursts into vivid combustion. A sheet of platinized platinum placed at the focus heats to whiteness.

The light filter extracts visible light, i.e., it filters out visible light from the complex energy wave, CEW. Visible light travels in concentrated dissipative form within the CEW; there are many ways to extract this concentrated visible light from the CEW. One process is by using an alum composition in solid, liquid or gas form. The solid form, for example, is a prism composed by an alum solution. In this case, see FIG. 1, when the said rays 325 (the regenerated consumer SOL) from the CEW pass through the objective mirror-lens system 380 and hit the alum solution 390, visible light 395 is filtered out. Therefore, as known in the art since Newton, by placing a prism in axial alignment with the alum compound 390, all the color spectrum of visual light can be seen. In operation, the optical conduit's carrying the CEW 110, is optically coupled through the coupler 310 to the said distributor collimator 320 in optical alignment with a focusing and collimating system 340, comprised of mirrors and prisms, to capture, align and focus the light rays 325 (the regenerated consumer SOL), so that the rays 385 are directly focused onto the said alum solid, liquid or gas solution 390 from which a highly focused, collimated and over-concentrated visible light 395 is filtered out. All other rays of the luminous spectrum are blocked off. Small reflectors placed along the optical axis of the visible light 395 serve as optical lamps. A conduit of fiber optics can also take the visible light to local destinations of a building, for example, where at distal ends the optical lamps are installed.

The Electricity Filter extracts electricity, i.e., it filters out or transforms into electricity certain components of the complex energy wave, CEW, like vibration, heat, magnetic and electric fields. These components travel in concentrated dissipative form within the CEW; there are many ways to extract and convert these concentrated components from the CEW. For example piezoelectricity is a process that converts mechanical stress into voltage, and vice-versa, through piezo generators and piezo motors, respectively. The process per se is well known in the industry. It can be used in one embodiment by the use of ceramic sheets placed in front of the light rays 325 (the regenerated consumer SOL) as high dense waves vibrate onto the ceramic, creating mechanical stress and enabling the ceramic to produce voltage. Electromagnetism is another known process and can be utilized in the present invention as the said light rays 325 can be passed into magnetic tubes and pipes—inductors coiled around these pipes or tubes generate voltage. One process, see FIG. 1, to convert heat into electricity comprises in using a thermo-electric semiconductor compound 370. This converter 370 is composed of an array of PN silicon junctions 371. Blackened-receiving plates 372 are attached to one side of the said PN junction 371 to absorb maximum of the incoming radiant energy. Fins 373 are attached to the other side of the said junction 371. The converter 370 is enclosed in a box with glass windows 374 on the side facing the rays 365. Glass windows are transparent to most energy radiation from said SOL 325 but opaque to the rays of long wavelength which are emitted by the said heated receivers 372. In operation, the optical conduit/s carrying the CEW 110, is optically coupled through the coupler 310 to the said distributor collimator 320 in optical alignment with a focusing and collimating system 360, comprised of mirrors and prisms, to capture, align and focus the light rays 325 (the regenerated consumer SOL), so that rays 365 are directly focused onto the said glass windows 374 of the thermoelectric converter 370, from which a highly focused, collimated and overconcentrated beam creates a difference of temperature at the receiver plates 372 and a current is generated at the PN junctions 371 and available as an electric potential 375.

Claims

1.-15. (canceled)

16. A system for collecting and transmitting electromagnetic radiation through at least one disorder-enhanced optical conduit comprising:

a mirror-lens for concentrating scattered electromagnetic rays into a focal plane to produce focused rays;

a mirror concentrator for concentrating the focused rays by a N factor;

a coupler to align the focused rays;

a disorder-enhanced optical conduit having a distal end, said conduit receives and conveys the concentrated rays, generates a complex energy wave and transmits the wave to said distal end;

a collimator to convert the complex wave into focused rays;

a heat filter to filter the heat of the focused rays;

a light filter to filter the light of the focused rays; and

an electricity filter to filter the electricity of the focused rays.

17. The system of claim 16, wherein said mirror-lens includes one of a parabolic mirror, a circular-type mirror and a zoom lens system, and is optically coupled with said concentrator.

18. The system of claim 16, wherein said concentrator includes at least one mirror optically coupled with said conduit and is adapted to generate singular over-concentrated light.

19. The system of claim 16, wherein said optical conduit is configured to transmit a self-organizing energy wave to said distal end.

20. The system of claim 16, wherein said mirror concentrator system is adapted to concentrate the focused rays by a factor of one to one hundred million.

21. The system of claim 16, wherein said heat filter is configured to extract heat, wherein said light filter to configured to extract visible light, and said electricity filter is configured to extract electricity.

22. The system of claim 21, wherein said light filter is configured to extract and deliver white light using an optical lamp, wherein said heat filter is configured to extract infrared and deliver heat using a chemical compound, and wherein said electricity filter is configured to deliver electricity using at least one of a piezoelectric converter, a PN junction converter, a photovoltaic system.

23. The system of claim 22, wherein said optical lamp includes a chemical compound, at least one of solid, liquid, and gas, and an optical reflector axially aligned with the chemical compound to deliver visible white light.

24. A system for converting at least one of audible and non-audible waves into energy and transmitting it through at least one disorder-enhanced optical conduit, comprising:

a first reflective medium including an acoustic bowl;

a second refractive medium including an objective lens;

a mirror system concentrator;

a disorder-enhanced optical conduit;

a coupler;

a focusing collimator;

a distributive collimator;

a heat filter and converter;

a light filter and converter; and

an electricity filter and converter.

25. The system of claim 24, wherein said acoustic bowl is a concave reflective surface comprised of at least one of metal, ceramic, glass, and organic compound that captures audible and non-audible waves.

26. The system of claim 24, wherein said second refractive medium contains at least one of a refractive lens and a zoom-lens system.

27. The system of claim 24, wherein said mirror system concentrator includes at least one mirror optically coupled with said conduit and is capable of generating singular over-concentrated light having an extremely narrow ray width and high radiant energy.

28. The system of claim 24, wherein said optical conduit is configured to propagate energy as a complex energy wave.

29. A system for collecting energy from at least one of radiant and mechanical sources, the system comprising:

a collector configured to capture energy and to direct the captured energy toward a concentrator;

a concentrator configured to receive the directed energy and to concentrate the energy;

a disorder-enhanced structure; and

a coupler configured to receive the concentrated energy, leading the energy onto said disorder-enhanced structure, wherein the energy's rays are scattered, generating a complex energy wave in said structure.

30. The system of claim 29, wherein said collector includes at least one parabolic mirror and lens system for collecting rays indicative of solar radiation.

31. The system of claim 30, further comprising an optical compound configured to receive the captured rays through said parabolic mirror and said lens system.

32. The system of claim 29, wherein said collector comprises an acoustic bowl for collecting mechanical energy indicative of acoustic radiation.

33. The system of claim 29, further comprising reflection and refraction lenses to focus and capture mechanical energy through said acoustic bowl.

34. The system of claim 29, wherein said concentrator comprises at least one of a lens, a mirror, a scatterer, and an angular filter.

35. The system of claim 34, wherein said concentrator is an image forming concentrator.

36. The system of claim 34, wherein said concentrator is a non-image forming concentrator.

37. A system for transmitting electromagnetic radiation through at least one of a disorder-enhanced optical conduit and a disorder-enhanced structure comprising:

a disorder-enhanced optical conduit having a distal end, said conduit receives electromagnetic rays, generates a complex energy wave and transmits it to said distal end; and

a disorder-enhanced structure, said structure receives electromagnetic rays, generates and transmits a complex energy wave.

38. The system of claim 37 and further comprising a second optical conduit and wherein said conduits are arranged to form an optical cable.

39. The system of claim 37 wherein said optical conduit and said disorder-enhanced structure are fabricated of at least one of glass, nanocompounds, organic, inorganic, and bio-inorganic compounds.

40. The system of claim 37 wherein said optical conduit and said disorder-enhanced structure are enhanced with at least one of nanostructured and non-nanostructured scatterers configured to produce high particle density with least optical crowding.

41. The system of claim 37 wherein said optical conduit has a diameter between 1 micrometer and 10 centimeters.

42. The system of claim 37 wherein said diameter has a proportional relation to an energy density index.

43. The system of claim 37 wherein said optical conduit and said disorder-enhanced structure have a length between 1 micrometer and 100,000 kilometers.

44. The system of claim 37 wherein said optical conduit is heat-resistant.

45. The system of claim 37 wherein said optical conduit and said disorder-enhanced structure are nanostructured for optical scattering and adapted to transmit chaotic dissipative wavelike signals.

46. The system of claim 37 wherein said optical conduit and said disorder-enhanced structure are nanostructured for optical scattering and adapted to transmit self-organized wavelike signals.