JPH11238947A - Holography nuclear fusion reactor bin also using gravitational wave utilizing semiconductor laser array variable oscillating hologram bin by semiconductor laser array variable oscillation hologram, and gravitational-wave holography method and device thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a detailed form, to make it possible to operate even with an opaque container, and to make it possible to perform the effective absorption and the utilization of energy and technologically free utilization of gravitational waves, by identifying the hologram-shaped pattern made by the contrast mode by the oscillation and the stopping of the laser of a semiconductor laser element in the hologram. SOLUTION: When many semiconductor laser elements 6 are aligned in line and a spherical wave 8 is generated from each laser element 6, the synthesized wave of these spherical waves 8 forms the next wave front. When a control circuit layer 7 is utilized and the phases of the oscillating spherical waves 8 are synchronized, the coherent spherical waves 8 can be generated. Furthermore, the interference-fringe pattern made by the contrast made by the oscillation (ON) and the stop (OFF) of the coherent spherical wave 8 from the semiconductor laser elements 6 aligned in line by utilizing the control circuit layer 7 can be identified in the ordinary hologram. ON is in correspondence with bright, part, i.e., transparent part of the hologram, wherein the laser passes, and OFF is in correspondence with the opaque part of the hologram, which shields the laser.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to Japanese Patent No. 202
No. 5180 (a method and an apparatus for applying energy to a substance using a holographic technique. The method of holography using a light shell) shown in
And the device. That is, the present invention relates to a method of holographic fusion using a holographic split traveling multi-shell, a holographic machine tool, a holographic gravitational wave generator, and the like, and an improvement and development of the apparatus.

[0002]

2. Description of the Related Art Conventional technology, that is, Japanese Patent No. 20
In No. 25180 (a method and an apparatus for applying energy to a substance by using a holographic technique. The method of the electronic variable hologram) was abstract. In addition, since the hologram used for the hologram uses a transparent hologram container to utilize a reproduction light from the outside, effective absorption and utilization of the energy generated by nuclear fusion were insufficient retrospectively.
The holographic fusion reactor system disclosed in Japanese Patent No. 2025180 utilizes only the pressure of a holographic split traveling multi-shell. Further, the gravitational wave generator simply generates a gravitational wave. Here, the conventional technique described above, that is, Japanese Patent No. 2025
No. 180 (a method and an apparatus for applying energy to a substance using the holographic technique. The invention by the present inventor) is summarized as follows. As a method of confining and moving matter using holographic technology, we first create a so-called split traveling multiple light shell. The split / progressive / multiplex / light shell has a quadruple function, and the function evolves in the order of light shell, multiple light shell, progressive multiple light shell, and split progressive multiple light shell. First, a light shell is a set of hollow spherical shell-shaped focal points created by a real holographic image. When a substance (plasma, for example) in the interior touches the shell-shaped focal point, the substance is heated and accelerated, causing an explosion and implosion phenomenon. Cause As a result, about one half of the plasma
Explodes toward the outside of the light shell, and about one-half explodes toward the inside of the light shell. In other words, a substance can be confined inside the light shell using this implosion phenomenon. Next, the multiple light shell means that about one half of the plasma emitted to the outside of the second light shell from the inside explodes toward the outside of the second light shell, and about one half of the plasma comes out of the second light shell. 2 Explode toward the inside of the light shell. In the same manner, about 1,024th of the entire light exits outside the tenth light shell. As described above, the multiple optical shell has a remarkably improved material confinement force as compared with the single optical shell. Next, the traveling multiple light shell means that an (n + 1) th light shell is formed outside the nth light shell, and all light shells are continuously reduced,
The (n + 1) th light shell is moved to the position of the nth light shell. Therefore, at the same time, the first light shell comes to the position of the 0th light shell further inside and disappears at that point. This traveling multiple light shell can confine all the plasma inside. Next, with the split traveling multiple light shell, the light shell surface is split into many parts, and
Each of the divided surfaces is divided toward the center of the shell sphere, and the plasma confinement force is adjusted for each divided unit. Therefore, it is possible to completely confine the plasma stably while maintaining the overall shaping corresponding to the change in the internal pressure. The confinement force of the split traveling multiple optical shell depends on the confinement force per unit area, but the confinement force can be increased by using an electromagnetic wave having a small wavelength. Therefore, the split traveling multiple optical shell can freely confine and compress the substance. Further, by giving eccentricity to the confinement force, the confined substance can be moved. Therefore, various devices can be manufactured by using the split traveling multiplex optical shell. In Example 9 of Japanese Patent No. 2025180, "Method and Apparatus for Initiating Controlled Nuclear Reaction Using Holographic Technology" and Example 10 "Holographic Technique Using Holographic Technology" Example 11: "Particle accelerator using holographic technology" in Example 11 and Example 12: "Holographic machine tool using holographic technology" And a device for carrying the material during the work.

[0003]

The problem to be solved by the present invention is firstly the above-mentioned conventional Japanese Patent No. 20251.
Although the method of the electronic variable hologram shown in No. 80 is abstract, a more specific form is required. Secondly, while the above-mentioned electronic variable hologram uses a transparent hologram container in order to utilize a reproduction light from the outside, a method is required in which an opaque container can be used. Third, there is a need for a new method capable of effectively absorbing and utilizing the energy generated by holographic fusion or the like using the above-mentioned electronic variable hologram. Fourthly, while the conventional holographic fusion reactor uses only the pressure of the holographic split traveling multi-shell, a more sophisticated and compact fusion reactor using attractive force is also used. The method of the above is demanded. Fifth, the conventional gravitational wave generator simply generates a gravitational wave, but attempts to establish a method that enables technically free use of the gravitational wave. Things.

[0004]

The first object of the present invention, that is, a means for solving a more specific form of an electronic variable hologram, is a semiconductor laser array (a large number of semiconductor laser elements are arranged in a matrix). Hologram-like pattern of bright and dark of the laser oscillation and stop of the semiconductor laser element is identified as a hologram, and the laser oscillation of the semiconductor laser element is identified. A “semiconductor laser array variable oscillation hologram”, which is one type of an electronic variable oscillation hologram, which is identified as reproduction light (reference light), is used.
Means for solving the above-mentioned second problem, that is, a method which is also possible in an opaque container, utilizes a “semiconductor laser array variable oscillation hologram bin” in which the above-described semiconductor laser array variable oscillation hologram is installed in a container. .
In order to solve the third problem, that is, a new method capable of effectively absorbing and utilizing energy, a conventional transparent hologram container using a reproduction light from the outside requires a nuclear hologram. Utilizes a "holographic fusion reactor bin" of opaque containers made possible by utilizing a semiconductor laser array variable oscillation hologram bin which allows for efficient absorption and utilization of the energy generated by the fusion. Further, the above-mentioned fourth problem, that is, means for solving the system of a more high-performance and compact fusion reactor using attraction, the method of the conventional holographic fusion reactor, as means for confining plasma, In contrast to the method using only the pressure of the holographic split traveling multi-shell, a gravitational wave generator (Japanese Patent No.
Example 11 of No. 25180. By installing the invention of the present invention) in the center of the inside of the light shell, a "holographic fusion reactor bin combined with gravity wave" utilizing the generated attractive force is utilized. Also, the fifth problem described above, namely,
Means for solving the method of enabling the technical free use of gravitational waves is that the conventional gravitational wave generator only generates gravitational waves, whereas the conventional gravitational wave generator merely generates gravitational waves. "Gravitational wave holography" that enables precise technical use
Use

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First, a "semiconductor laser array variable oscillation hologram" will be described. A variable oscillation hologram can be created using a semiconductor laser array in which the phase of the oscillation laser is synchronized. This variable oscillation hologram is not only a variable hologram but also a reproducing light generator. That is, the variable oscillation hologram has a conventional holographic function. Hereinafter, it will be described in detail. Here, the principle of the conventional ordinary hologram will be described as follows. When the object light, which is the light from the object, and the reference light obliquely interfere with each other,
The maximum appears when the peaks of the waveforms of the object light and the reference light overlap each other. Therefore, when this maximum is recorded on a film, the film becomes transparent. This is a transparent portion of the interference fringe of the hologram, and information (maximum) of the phase of the object light is recorded on the transparent portion. Of course, it is also information (maximum) of the phase of the reference light. Next, when this hologram is irradiated with reference light (reproducing light), the transparent portion becomes brighter, and the maximum of the reference light appears. At the same time, this is the same place as the maximum of the object light. It will be included in the diffracted light diffracted by the hologram. Accordingly, a three-dimensional image of the object including the phase information of the object light in the diffracted light is reproduced. However, there are virtual images and real images of the reproduced object. In a normal hologram of a three-dimensional photograph, a virtual image is reproduced at a place where the original object was, and a real image is reproduced at a position which is angularly shifted by twice the incident angle of the reference light. In computer holography, if a hologram of an arbitrary virtual object is calculated by a computer to create an interference fringe pattern, a hologram is used as the hologram to irradiate reproduction light to realize a stereoscopic real image of the virtual object. That is, the equivalent of the hologram of the virtual object shown above can be realized by the interference fringe pattern of the blinking of each laser element in which a large number of laser elements of the semiconductor laser array are arranged in a matrix. In this case, if the laser oscillation of each laser element is "dot" and the laser stop is "dark", the point corresponds to the transparent part of the conventional ordinary hologram, the point corresponds to the opaque part, and the interference by the combination The striped pattern has the function of a hologram, and at the same time, is a device for generating reproduction light. In this case, since the laser oscillated by the laser element has a spherical wave shape that spreads radially, the combined wave of the laser from each laser element forms the next wavefront, and the whole becomes holography. In addition, since this blinking can be changed at high speed and freely by computer control, it has a function of a variable hologram. In addition, the semiconductor laser array is 10 to 1 mm wide and 1 mm wide.
Since the elements can be arranged at a ratio of 00, that is, 100 to 10,000 or more, it is enough to form a hologram. When a large hologram is formed and a small image is reproduced, a higher-resolution image can be reproduced. The phase of the oscillating laser is not limited to the one in which the phases are synchronized, and the hologram can be formed by calculation for freely controlling the phases of the oscillating lasers of a large number of laser elements. It is also possible to construct a hologram with high laser element utilization efficiency without stopping the laser by calculation based on a combination of the phases and amplitudes of the oscillation lasers of many laser elements. Second, a "semiconductor laser array variable oscillation hologram bin" can be formed using a semiconductor laser array variable oscillation hologram. This is because the conventional hologram used a transparent hologram container to use the reproduction light from the outside, so the effective absorption and utilization of the energy generated by nuclear fusion etc. was insufficient, It is a new method that can effectively absorb and use the generated energy. A semiconductor laser array variable oscillation hologram, its control circuit layer, and a power wiring layer are installed in a shell-like container, and a holographic split traveling multi-beam is formed in the inner space of the container by the operation of the semiconductor laser array variable oscillation hologram. Is a semiconductor laser array variable oscillation hologram bin. Third, the "holographic fusion reactor bin" will be described.
A holographic fusion reactor bin of an opaque container can be manufactured by using the above-mentioned semiconductor laser array variable oscillation hologram bin. The variable oscillation hologram of the semiconductor laser array is installed on the outer wall of a cylindrical transparent quartz glass container, and a control circuit and power wiring for operating the array are installed outside the laser array. Then, both ends of the cylindrical quartz glass container are narrowed to form an hourglass neck. Considering the structural strength of quartz glass and the transmission efficiency of radiant heat energy generated by nuclear fusion, both ends of the cylinder have a shape like a mouth of a glass bottle. With one of the ends facing upward and the other facing downward, the fusion fuel is introduced from above and the combustion material is discharged from below. Then, a holographic split traveling multiple light shell is formed in the inner space of the container by the variable oscillation hologram of the semiconductor laser array installed outside the quartz glass container, and the ultra-high temperature plasma of the fusion fuel is confined inside the light shell for nuclear fusion. Cause a reaction. The heat energy generated by the nuclear fusion reaction becomes electromagnetic radiation, reaches the inner wall of the quartz glass container, passes through the quartz glass layer, and reaches the semiconductor laser array layer. Here, if the laser array layer is composed of a cylindrical laser element and a gold group (for example, gold) filling between the laser elements, heat energy is efficiently transmitted to reach the control circuit layer and the power wiring layer. In the control circuit layer and the power wiring layer, the control circuit portion is made of a material of a normal integrated circuit, and the power wiring portion is made of gold and an insulating material. Also, since the electronic circuit and the power wiring portion are three-dimensionally configured, the gaps are filled with gold for heat conduction. In this way, the control circuit layer and the power wiring layer transmit heat energy efficiently and the heat reaches the outer wall. Here, the outside of the outer wall is further covered with gold. As described above, the variable oscillation hologram bin of the semiconductor laser array used for nuclear fusion is named a holographic fusion reactor bin.
The holographic fusion reactor bottle is housed in a sufficiently strong cylindrical stainless steel tank, and water is filled between the outer wall of the bottle and the inner wall of the tank. When the thermal energy generated by nuclear fusion passes through the bottle and reaches the outer wall thereof, it is absorbed by water to generate steam, and the steam can be used to turn a turbine generator to obtain electrical energy. Fourth, the "holographic fusion reactor bin with gravity wave" will be described.
By utilizing and developing the above-described holographic fusion reactor bin, a holographic fusion reactor bin combined with gravity waves can be produced. In other words, the holographic fusion reactor bottle system described above utilizes only the implosion pressure of the holographic split traveling multi-shell as a means of confining the ultra-high temperature plasma of the fusion fuel. On the other hand, by using gravity force generated by a gravitational wave generated by a gravitational wave generator (Example 11 of Japanese Patent No. 2025180; invention by the present inventor), a gravitational wave which is a more sophisticated and compact fusion reactor is used. A combined holographic fusion reactor bin can be made. Here, Japanese Patent No. 2025
The holographic gravitational wave generator shown in Example 11 of No. 180 is summarized as follows. According to Einstein's theory of gravitational waves (published in 1917), a changing mass quadrupole generates gravitational waves. For example, a rotating rod becomes a mass quadrupole. A mass quadrupole is obtained by expanding and contracting a material obtained by connecting two masses with a coil spring. A mass quadrupole also occurs when two masses are rotated 180 degrees in the same direction on the same circular orbit. However, the efficiency of gravitational wave generation by these methods is very low. For example, the output of a gravitational wave when one million tons of iron rod is rotated once per second is 10 −42 watts. In conclusion, large gravitational wave effects occur only in systems that run at speeds close to the speed of light and are very small and close to the radius of gravity. Two masses in circular orbit 1
As shown in a specific example in the case of rotating in the same direction at 80 degrees opposition, a mass of 500 kg is compressed to a diameter of 1/100 mm, and two 180 degrees are opposed to each other on a circular orbit having a diameter of 1/10 mm. Rotating at 90% speed produces about 1 trillion watts of gravitational waves. This equates to about 1.3 billion horsepower. Such a high-density compression of the mass and a rotation at an ultra-high speed can be realized by using a holographic split traveling multi-shell. However, the above specific example is an example, and when the output is not as high as 1 trillion watts, the condition is easier. However, it is needless to say that a higher output is also possible in principle. The above is Japanese Patent No. 20
This is a summary of the holographic gravitational wave generator shown in Example 11 of No. 25180, but there is a problem of an element used for the mass of the gravitational wave generator as a newly added matter. Here, the elements used for the masses M1 and M2 for the gravitational wave generator that must be compressed at an ultra-high density will be described. In order to generate gravitational waves effectively, the rotating mass must be compressed to an extremely high density. In general, light elements cause a nuclear fusion reaction at a certain high temperature and high pressure, and heavy elements cause a fission reaction at a certain high temperature and high pressure. All of them gradually undergo element conversion, and finally the most stable element, iron ( Element symbol Fe, atomic number 26). In the process of compressing the mass used for the gravitational wave generator from the normal density to the required ultra-high density, if the element used causes a nuclear reaction, expansion due to energy generation will hinder normal compression . In this case, if the element used for compression is iron, this problem can be avoided. Therefore, the element used for the mass for the gravitational wave generator is to use iron in principle. The tunable hologram bin of the semiconductor laser array can form a holographic split traveling multiple light shell inside the bin, but at the same time, the gravitational wave is placed in the internal space of the holographic split traveling multiple light shell containing the plasma. A generator can be made. In this case, the fusion fuel plasma is confined inside by the implosion pressure of the holographic split traveling multi-shell, and at the same time, is attracted toward the center by the gravitational wave attractive force of the gravitational wave generator.
In addition, the attractive force of gravitational waves not only confines the plasma inside the holographic split traveling multi-shell, but also
Nuclear fuel particles outside are also sucked one after another and taken into the light shell. Here, two examples of the gravitational wave generator used in the above-mentioned fusion reactor will be described below. The first example is to add two masses in a circular orbit of 180
A case in which one or two or more gravitational wave sources that are generated and propagated in a donut shape by a primary rotation only square wave generator that is rotated in the same direction while facing each other are arranged and the attractive force is used. In addition, the second example is to add two masses to the primary rotation rotated in the same direction at 180 degrees opposite to each other on a circular orbit, and to add the secondary mass orthogonal to the primary axis of the primary rotating circular orbit at the center. This is a case in which one or two or more gravity wave sources that are generated and propagated in a spherical shape by a spherical gravity wave generator that applies a secondary rotation that rotates the two masses about an axis are arranged and the attractive force is used. Thus, by using both pressure and attractive force for plasma confinement, a holographic fusion reactor with gravitational waves becomes a more sophisticated and compact fusion reactor. In this manner, the variable oscillation hologram bin of the semiconductor laser array in which the holographic fusion reactor combined with gravitational waves is formed is referred to as a holographic fusion reactor bin combined with gravitational waves. Fifth, while the conventional gravitational wave generator simply generates a gravitational wave, here, "gravitational wave" that enables precise and free technical use of the gravitational wave is described. Wave holography ". The gravity wave used in the gravity wave holography is the above-mentioned spherical gravity wave. That is, when the two masses are added to the primary rotation rotated in the same direction at 180 degrees on a circular orbit, the two masses are rotated around a secondary axis that is orthogonal to the primary axis of the primary rotating circular orbit. A gravitational wave source that generates and propagates in a spherical shape by a spherical gravitational wave generator with a secondary rotation that rotates two masses is used. As described above, a spherical gravitational wave generator can be manufactured by using a semiconductor laser array variable oscillation hologram. Next, a gravitational wave hologram is created by using the spherical gravitational wave generator. Fortunately, the gravitational wave generator, which is a set of masses for generating spherical gravitational waves, is very small.
It can be arranged in a large number of matrices at a rate of one to 10,000 or more. Here, the phase-synchronized blinking of the spherical gravitational wave of a spherical gravitational wave generator (hereinafter, referred to as a spherical gravitational wave element) in which many are arranged in a matrix, that is, ON / OFF.
The interference fringe pattern weave becomes a gravitational wave hologram. Specifically, the state where the mass of the spherical gravitational wave element is rotating on the orbit is ON, and the state where the rotation is stopped is OFF. In this case, even if the rotation is stopped, the compression of the mass is continued. This gravitational wave hologram is a gravitational wave variable hologram in the sense that the spherical gravitational wave element can be freely turned on and off. Further, since the spherical gravitational wave element also functions as gravitational wave oscillation, it is a gravitational wave variable oscillation hologram. Here, when this gravitational wave variable oscillation hologram is examined, if this is a planar hologram, a conjugate focal point is formed at a position symmetrical with respect to the hologram plane when a focus of the gravitational wave (targeting a real image; the same applies hereinafter) is created. Occurs. This conjugate focus is unnecessary and must be eliminated. This conjugate focus occurs because spherical gravitational waves emitted from a plane gravitational wave hologram, which is a matrix of spherical gravitational wave elements, are generated symmetrically on both sides of the hologram plane. As described above, since it cannot be easily blocked by a substance, a geometrical method is used to eliminate this conjugate focal point instead of blocking by a substance. That is, by making the gravitational wave hologram a curved surface instead of a flat surface, the focus of the gravitational wave becomes asymmetric with respect to the plane, and a conjugate focal point does not occur at a plane-symmetric position. If the gravitational wave hologram is formed into a spherical shape, which is a typical curved surface, when the focus of the gravitational wave is formed, the gravitational wave on the opposite surface side of the hologram surface is diffused and not focused, so that the conjugate focus can be eliminated. The gravitational wave variable oscillation hologram as described above can be realized by using the semiconductor laser array variable oscillation hologram, but can be more effectively realized by using the semiconductor laser array variable oscillation hologram bin. The spherical gravitational wave variable oscillation hologram can be more effectively realized by using a spherical semiconductor laser array variable oscillation hologram bin using a spherical container. As described above, the gravitational wave variable oscillation hologram is provided with a variable gravitational wave holography element, and is nothing less than a “variable gravitational wave holography”. Hereinafter, unless otherwise specified, "variable" is omitted, and this is simply called "gravitational wave holography".

[0006]

【Example】

Embodiment 1: A method of a semiconductor laser array variable oscillation hologram and an apparatus therefor. A variable oscillation hologram can be created using a semiconductor laser array in which the phase of the oscillation laser is synchronized. Figure 1 shows Hall 2 2
It is a secondary spherical wave. When the beam 3 is irradiated on the screen 1, the screen 1
A secondary spherical wave 4 is generated from each of the holes 2 arranged in the matrix. The composite wave of these secondary spherical waves 4 forms the next next wavefront. The same thing as the above-mentioned secondary spherical wave 4
It can be realized by the radial spherical wave 8 of the semiconductor laser array of FIG. When a large number of semiconductor laser elements 6 are arranged in a matrix and a spherical wave 8 is generated from each laser element 6, a composite wave of these spherical waves 8 forms the next wavefront. When the phase of the oscillating spherical wave 8 is synchronized using the control circuit layer 7, a coherent spherical wave 8 can be generated. Here, further consider an interference fringe pattern in which the coherent spherical wave 8 is oscillated (ON) and stopped (OFF) of the coherent spherical wave 8 from the semiconductor laser elements 6 arranged in a matrix using the control circuit layer 7. This can be identified as a conventional ordinary hologram. ON corresponds to bright, ie, the transparent portion of the hologram that the laser transmits, and OFF corresponds to dark, ie, the opaque portion of the hologram that blocks the laser. Therefore, the interference fringes woven by the OFF of the semiconductor laser element 6 are similar to the interference fringes of the hologram, and the ON of the semiconductor laser element 6 on the opposite side is similar to the transparent surface between the interference fringes. The fact that the ON of the semiconductor laser element 6 is similar to the transparent surface between the interference fringes means that the laser oscillation due to the ON corresponds to the maximum. Then, the composite wave of the maximum spherical wave 8 due to the turning on of a large number of semiconductor laser elements 6 becomes the next wavefront, and further aggregates to form a desired holographic real image. Note that what is useful here is a real image, as described above. FIG. 3 is a sectional view of the semiconductor laser array variable oscillation hologram. A large number of semiconductor laser elements 6 are arranged in a matrix, and a control circuit layer 7
The power wiring layer 9 controls the oscillation and stop of the laser of the laser element 6. In the interference fringe pattern interwoven with the oscillation and stop of the coherent laser light synchronized with the phase of the semiconductor laser element 6, the laser light 10 which is a composite wave of the spherical wave 8 oscillated by each laser element 6 forms a sequential wavefront. The holographic real image 11 is formed. It should be noted that the laser oscillated by the semiconductor laser element 6 may be one in which the phase of each laser element 6 is independently controlled, but holography is possible as long as it is calculated in such a manner.

Embodiment 2: Semiconductor laser array variable oscillation hologram bin method and apparatus. Example 1 above
The semiconductor laser array variable oscillation hologram bin can be manufactured by using the semiconductor laser array variable oscillation hologram of (1). FIG. 4 is a sectional view of a semiconductor laser array variable oscillation hologram bin. The quartz glass bottle 12 is a spherical shell-like container. A semiconductor laser array variable oscillation hologram composed of a matrix array layer of laser elements 6, a control circuit layer 7, and a power wiring layer 9 is provided outside the quartz glass bottle 12. A holographic real image 11 can be formed inside the bin 12 by the action of the holographic laser 10 oscillating when the semiconductor laser array variable oscillation hologram is activated. In addition, a semiconductor laser array variable oscillation hologram composed of a matrix array layer of laser elements 6, a control circuit layer 7, and a power wiring layer 9 is installed inside the quartz glass bottle 12, and the laser of the laser element 6 oscillates and stops. However, in this case, the shell-shaped container 12 may be opaque.

Example 3 Holographic Fusion Reactor Bin Method and Apparatus By using the semiconductor laser array variable oscillation hologram bin of the second embodiment, a holographic fusion reactor bin can be manufactured. FIG. 5 is a cross-sectional view of an example of a holographic fusion reactor bin using the semiconductor laser array variable oscillation hologram 13. In this case, the six English glass bottles 12 have both ends shaped like an hourglass neck and like a bottle mouth. The semiconductor laser array variable oscillation hologram 13 is set outside the quartz glass bottle 12 and is supported by the support 15 with both ends of the bottle 12 up and down. Also, a nuclear fuel injector end 16 is connected to the outside of the upper mouth of the bottle 12, and a nuclear fuel exhaust suction end 17 is connected to the outside of the lower mouth. Semiconductor laser array variable oscillation hologram 1 in this fusion reactor bin
Since the outside of 3 is in contact with the water of the boiler, it is coated with gold for corrosion and protection of the hologram 13 and the like. The holographic laser 10 that oscillates when the semiconductor laser array variable oscillation hologram 13 is operated can form a holographic split traveling multiplex light shell 14 (cylindrical and hemispherical at the upper and lower ends) in the center of the inside of the bin 12. I can do it. When the inside of the bin 12 is evacuated by operating the nuclear fuel exhaust inhaler and the nuclear fuel H is injected downward 18 from the nuclear fuel injector end 16, the nuclear fuel H is diffused into the bin 12. The diffused nuclear fuel H is a holographic split traveling multi-shell 14
And is heated by compression to cause a nuclear fusion reaction. This nuclear fusion reaction occurs inside the holographic split traveling multi-shell 14, but the nuclear fuel H is mainly absorbed from the upper part of the shell 14, and gradually moves to the lower part while causing the nuclear reaction to move to the lower part of the shell 1.
4 (discharged by reducing the confinement force). Nuclear fuel exhaust H discharged from the light shell 14
e is discharged from the nuclear fuel exhaust inhaler end 17 at the bottom of the bin 12. When the energy (electromagnetic wave) generated by the nuclear fusion reaction reaches the quartz glass bottle 12 of the transparent container, it penetrates the quartz glass bottle 12 and passes through the quartz glass bottle 12 (= 6 + 7 + 9).
Reach Since this laser array layer 13 is opaque, energy is transmitted to external water by heat conduction. In this case, the transmitted energy per unit area increases as the thickness of the glass of the quartz glass bottle 12 decreases, but the thicker the glass, the stronger the strength in terms of structural mechanics. Further, since the semiconductor laser array layer 13 has a very small thickness, the thermal conductivity is high. However, this is due to the space between the semiconductor laser elements 6 arranged in a matrix (half of the total area of the elements). The heat is transmitted to water by conduction mainly in the part made of gold. Quartz glass 1 in the space between them
The two surfaces are blackened to increase the heat absorption. FIG. 6 is a cross-sectional view of the upper portion of the holographic fusion reactor bin. The electromagnetic wave energy 20 generated by nuclear fusion reaching the end of the quartz glass bottle 12 has a low transmittance of the electromagnetic wave L1 (a part of 20, hereinafter the same) because the thickness of the quartz glass 12 is increased in structural strength. . Therefore, if the glass surface of this portion is inclined with respect to the traveling direction of the electromagnetic wave L1,
The amount of energy per unit area decreases, and the reflected light L3 relative to the refracted transmitted light L2 (part of 20, hereinafter the same)
(Part of 20, the same hereinafter) increases. The reflected light L3 diffuses to a portion where the other direct light 20 per unit area is small and transmits through the glass. The shape for achieving this is a funnel-like shape like a constricted portion of an hourglass. In addition, the shape of this end portion becomes a shape like a mouth of a glass bottle because the glass thickness becomes thicker in order to obtain structural strength in order to attach the bottle 12 to the support. This is because if the shape of the end of the quartz glass bottle 12 is semicircular and the thickness of the glass is the same as that of the cylindrical portion, even if the transmission of the electromagnetic wave energy 20 is normal, the object necessary to support the bottle 12 is not formed. This is because the contact between the bottle 12 and the water is hindered, and when the output is high, the bottle 12 and other laser elements 6 and the like are melted due to insufficient cooling. FIG. 7 is a detailed horizontal sectional view of the wall of the holographic fusion reactor bin. Thickness D1
The semiconductor laser array layer 13 (= 6 + 7 + 9) having a thickness D2 is formed on the quartz glass 12 of the first embodiment, and a main power trunk 21 is wired outside the power trunk layer 9. The main power wiring 21 is a gold wire.
2 The purpose of the gold coating 22 is to protect wiring and prevent corrosion with respect to contact with boiler water. Also, the main power wiring 21 forms vertical stripes in the vertical direction to reduce the resistance of the boiler water flow, and
The function of canceling the vibration of No. 2 by interference is provided. The decrease in water flow resistance due to the vertical stripes is found in sperm whale skin and the like in nature. FIG. 8 is a sectional view of a power generation boiler in which a holographic fusion reactor bin 23 is housed in a stainless steel tank 24 and used as a heat source. The fusion reactor bin 23 is placed inside the tank 24, and the upper and lower sides are set on the support (15 '+ 37, 15' + 24). The support cover 15 'is covered and fixed with bolts 39. The tank lid 37 is fixed with bolts 38. Water pipe 40 to water surface 40
Water supply 35 until. The power supply 41 is connected to the fusion reactor bin 23. The operation of the fusion reactor bin 23 is as described above, but the water in the tank 24 is heated by the thermal energy generated by the fusion. The heated water is 40
The steam turns into steam and is sent to the turbine generator via the steam pipe 30. The high-temperature steam that has turned the turbine turns into water in the double water device and circulates again to the boiler, but is heated by the steam that has exited the turbine and sent to the water supply pipe 31 in the same manner as in the case of turbine power generation by a normal boiler. It is.

Embodiment 4: Method and apparatus for a holographic fusion reactor bottle with gravitational waves. By utilizing the holographic fusion reactor bin 23 of the third embodiment, a holographic fusion reactor bin combined with gravity waves can be manufactured. Conventional Holographic Fusion Reactor System (Example 9 of Japanese Patent No. 2025180. Invention by the Inventor)
Used only the implosion pressure of the holographic split traveling multi-beam shell BSNK. In addition, the gravitational wave generator (Example 1 of Japanese Patent No. 2025180) was used.
One. By using the attractive force of the gravitational wave generated by the inventor of the present invention, it is possible to produce a holographic fusion reactor bin combined with a gravitational wave, which is a more sophisticated and compact fusion reactor. Here, the holographic gravitational wave generator shown in Example 11 of Japanese Patent No. 2025180 is as described in the “Embodiment of the Invention”, but is summarized as follows. The changing mass quadrupole produces a gravitational wave. When two masses are rotated 180 degrees in a circular orbit in the same direction, they become mass quadrupoles. Large gravitational wave effects occur only in systems that run at speeds close to the speed of light and are very small and close to the radius of gravity. FIG. 9 is a diagram illustrating the principle of generation of gravitational waves. When two masses M1 and M2 having a diameter φ are rotated at a speed v in the same direction at 180 degrees on a circular orbit with a radius R, the masses become quadrupoles and gravitational waves are generated. FIG. 10 is a horizontal cross-sectional view of a magatama type bipolar gravitational wave generator (this device is made of a mass and a holographic light shell). Since the holographic split traveling multiple light shell BSNK acts to confine the substance inside by the implosion pressure, the masses M1 and M2 which rotate on the circular orbit R at the speed v in the direction of the arrow show the pressure in the traveling direction. Pressed. Therefore, the split traveling multi-shell BSN
K can be added behind the direction of travel to increase propulsion. Since the direction of the propulsion force vector with respect to the masses M1 and M2 is inside the tangent direction of the circular orbit R, when considered at a certain moment of time, the split traveling multiple light shell BSNK added to the rear is outside the tangential direction. However, in actuality, it takes time to transmit the propulsion force, and its shape is bent inward so that the substance inside the split traveling multiple light shell BSNK added at the back does not detach in the tangential direction. It takes the shape of a jewel. FIG. 11 is a horizontal sectional view of a magatama type tripolar gravity wave generator. The function is similar to that of the above-mentioned magatama type bipolar gravitational wave generator. As the number of poles increases, the frequency of the generated gravitational wave increases when the rotation speed is the same. However, when the mass becomes a continuous donut shape, no gravitational wave is generated. The holographic fusion reactor bin 23 can form the holographic split traveling multiple light BSNK therein, but at the same time, the holographic split traveling multiple light shell B confining its plasma.
A gravitational wave generator (this device is made of mass and holographic light shell) can be made in the internal space of SNK. FIG. 12 shows a holographic fusion reactor bin 23.
FIG. 2 is a horizontal cross-sectional view of a holographic fusion reactor with gravitational waves formed inside the holographic fusion reactor. Holographic laser λ
1 forms a split-progression multi-beam shell BSNK for a holographic fusion reactor. Next, the split traveling multiple light shell B
A gem-shaped bipolar gravitational wave generator m is formed in the center of the light shell BSNK by using a holographic laser λ2 inside the SNK. The fusion fuel H is confined and heated by the split traveling multiple light shell BSNK by the holographic laser λ1. In addition, magatama type gravitational wave generator m
Traveling multiple light shell BS due to the gravitational wave attractive force generated
Nuclear fusion fuel H outside and inside NK is light shell BSNK
Attracted towards the center of the As a result, the density of the plasma of the fusion fuel H is improved, and a high-performance fusion reactor is obtained.

Example 5: Method of gravitational wave holography,
And the device. A holographic gravitational wave holography method and a holographic gravitational wave holography method can be manufactured using the holographic gravitational wave generator (invention by the present inventor) described in Example 11 of Japanese Patent No. 2025180. As shown in Example 4, the changing mass quadrupole produces a gravitational wave. Specifically, when two masses are rotated 180 degrees in a circular orbit in the same direction, they also become mass quadrupoles. However, the gravitational waves generated therefrom are generated in a donut shape around a rotating circular orbit of mass, and propagate and propagate. This form of expansion propagation is insufficient when gravitational waves are used as holography. In conclusion, if a spherical gravitational wave is generated around the center of a rotating circular orbit of mass, it can be used to create gravitational wave holography. FIG. 13A shows a case where two masses M1 and M2 rotate in a circular orbit having a radius R about the Z axis.
Polar gravity wave generator (mass M1, M
A light shell for compressing and accelerating 2 is omitted. same as below. FIG. 4 is a cross-sectional view showing a state of propagation of a gravitational wave 42). FIG. 13B is a plan view of FIG. 13A viewed from the Z-axis direction. In this case, the gravitational wave 42 propagates in a donut shape with the circular orbit R as the center. Next, a method of generating a spherical gravitational wave using this will be described below. FIG.
FIG. 4A is a plan view showing a state in which a spherical gravitational wave laser is generated by a bipolar gravitational wave laser generator having a secondary rotation axis (Y axis). (B) of FIG. 14 is (b)
2 is a cross-sectional view as viewed from the Z-axis direction. FIG. 14A shows a state in which the bipolar gravitational wave generator is rotated in the direction of arrow 43 (called the secondary rotation direction) about the Y axis (called the secondary rotation axis). The state rotated by 90 degrees is the mass M
This is the position of the bipolar gravitational wave generator consisting of 1 'and M2'. FIG. 14B shows a state in which the bipolar gravitational wave generator is rotated around the Y axis 44 which is the secondary rotation axis. The position rotated by 90 degrees is the position of the bipolar gravitational wave generator including the masses M1 'and M2'. That is, FIG.
, The mass M in the circular orbit R of the gravitational wave generator
The donut-shaped gravitational wave 42 due to the primary rotation of 1, M2 is
A spherical gravitational wave is obtained by applying a secondary rotation about the Y axis. By controlling the rotation of the spherical and gravitational waves, a coherent spherical gravitational wave, that is, a spherical gravitational wave laser can be obtained. FIG. 15 is a trajectory of the mass (M1, M2) obtained by adding the secondary rotation to the primary rotation when the spherical gravitational wave laser is generated. FIG. 15A is a plan view thereof. FIG. 15B is a side view thereof. FIG.
In (a) of FIG. 5, if the trajectory on the spherical surface of the radius R of the mass M1 is shown in order from k1, k1, k2, k2 ', k
3 ', k3, k4, k4', k5 ', k5, k6, k
6 ', k7', k7, k8, k8 ', k9', k9, k
10, k10 ', k11', k11, k12, k1
2 ′ and k1 ′. The mass M2 is on the opposite side of the sphere center of radius R with respect to the mass M1. In (b) of FIG.
The trajectory of the mass M1 on a hemisphere with a radius R is shown. Mass M
2 is on the opposite side of the sphere center of radius R with respect to the mass M1.
The trajectory obtained by adding the secondary rotation to the primary rotation is represented by the mass (M
1, M2), a spherical gravitational wave laser is generated. Next, a method of making a gravitational wave hologram using the spherical gravitational wave laser will be described. FIG.
Is a sectional view showing a part of a gravitational wave hologram having a thickness Δd. Each gravitational wave laser element constituting a part of the gravitational wave hologram is a spherical gravitational wave laser generator. The mass of the spherical gravitational wave laser generator (M1,
M2) generates a spherical gravitational wave laser 45, which is a coherent spherical gravitational wave, by performing primary rotation and secondary rotation (rotation axis 44) and adjusting the rotation speed. Then, the composite wave of the spherical gravitational wave laser 45 generated from each spherical gravitational wave laser generating element forms the next wavefront. When the rotation of the spherical gravitational wave laser generating device, which is the spherical gravitational wave laser generator, is stopped, the oscillation of the gravitational wave laser 45 is stopped. Here, when the state in which the gravitational wave laser 45 oscillates from the spherical gravitational wave laser generation element is set to ON, and the state in which the oscillation of the gravitational wave laser 45 stops is set to OFF, the ON and OFF in which a large number of elements are arranged in a matrix form. The interference fringes act as gravitational wave holograms. That is, ON and OF
A spherical gravitational wave laser oscillating with an interference fringe pattern interwoven with F becomes a gravitational wave hologram, and a composite wave thereof becomes a gravitational wave holographic laser. FIG. 17 shows gravitational wave holography in which a conjugate focal real image is generated. The gravitational wave hologram having a thickness Δd is obtained by arranging a plurality of spherical gravitational wave laser generating elements 46 in a matrix on a plane. The spherical gravitational wave laser and the gravitational wave holographic laser 47 generated by the generating element A6 form a focal real image F of the gravitational wave. At the same time, a conjugate focal real image F 'is formed at a symmetric position on the hologram. In this case, from the practical viewpoint, only the focal real image F is required, and the conjugate focal real image F 'is unnecessary and obstructive. However, gravitational waves have high penetration power and cannot be easily cut off depending on the substance. Therefore, a method of erasing the conjugate focal real image F 'uses a geometric method. FIG. 18 shows gravitational wave holography in which a conjugate focal real image F 'is not generated. The gravitational wave hologram having a thickness Δd is obtained by arranging a large number of spherical gravitational wave laser generating elements 46 in a matrix on a spherical surface having O as a center. The gravitational wave holographic laser 47 oscillated by the spherical gravitational wave laser generation element 46 forms a focal real image F of the gravitational wave. At the same time, a gravitational wave holographic laser 47 is emitted to the opposite side of the hologram, but this diffuses and does not form a focused real image. Therefore, the conjugate focal real image F 'can be erased by this method. FIG. 19 is a sectional view of the gravitational wave holography apparatus. A semiconductor laser array variable oscillation hologram composed of a matrix arrangement of the semiconductor laser elements 6 and a control circuit layer 7 and a power wiring layer 9 is placed inside the ceramic spherical structure 48. Then, this ceramic ball structure 48
Is filled with a large number of iron balls (iron is the most stable element for nuclear reactions caused by ultra-high temperature and high pressure compression). And
When this semiconductor laser array variable oscillation hologram is operated, the internal iron ball is divided and compressed by the holographic division-progression multiple light shell BSNK, and the mass (M
1, M2), a gravitational wave hologram # 46 in which a number of spherical gravitational wave laser generating elements 46 are arranged in a matrix on a spherical surface inside a ceramic spherical structure 48 can be formed. By the gravitational wave holography laser 47 generated from the gravitational wave hologram # 46, a gravitational wave holography real image (49, 50) can be freely formed. The gravitational wave holography real image 50 formed inside is directly formed by the inward gravitational wave holography laser 47, while the gravitational wave holography real image 49 formed outside is formed by the gravitational wave holography laser 47 facing the real image 49. Formed through the wall.
Since the gravity wave has a large transmission power, the external real image 49 is also formed freely and with high precision. The holding of a large number of iron balls filled in the ceramic sphere structure 48 when the semiconductor laser array variable oscillation hologram is stopped is performed at a certain distance from the laser array layer 6 in the holographic split traveling multi-beam shell B.
A holding structure in which a pillar is extended from a part of the array layer 6 is manufactured by SNK, and an iron ball is held therein. Further, the holding of the iron does not necessarily have to be an iron ball as long as it is easily divided and compressed at the time of restart. For example, a three-dimensional lattice may be used.

[0012]

According to the method described above, a "semiconductor laser array variable oscillation hologram" can be produced by using a semiconductor laser array in which the phases of oscillation lasers are synchronized. Further, by using the semiconductor laser array variable oscillation hologram, a semiconductor laser array variable oscillation hologram bin can be formed. In addition, by using this laser diode array variable oscillation hologram bin, a holographic fusion reactor bin, which is a holographic fusion reactor of an opaque container, is created, and a "holographic fusion reactor" is installed inside the container.
Can be made. In addition, by using a tunable hologram bin with a semiconductor laser array, a holographic fusion reactor bin with gravitational waves in an opaque container and a holographic fusion reactor with gravitational waves in the interior space of the container Can be done. In addition, “gravitational wave holography” can be realized by applying the above techniques. Therefore, by using the present invention, a real image and a virtual image of electromagnetic wave holography and gravitational wave holography can be freely used. Since the electromagnetic holography using the semiconductor laser array variable oscillation hologram is a variable oscillation hologram with very high resolution, it is directly connected to a computer to limit the performance of the electromagnetic wave holography (the quantum well laser, which is a type of semiconductor laser, has a very high resolution). High). Thus, it can do almost anything electromagnetic holography can do. Other than shown in the present invention, for example, "holographic physical medical device" effective for hyperthermia of cancer, and "holographic machine tool"
(Canadian Patent No. 1186925, Japanese Patent Application No. 5
6-062396. Invention by the inventor. ), Etc. to improve performance. In addition, a "method for applying energy to a substance using a holographic technique and an apparatus therefor" described in the prior art (Japanese Patent No. 2025180).
Invention by the inventor. ) Of Examples 9 to 12, "Method and Apparatus for Performing a Controlled Nuclear Reaction Using Holographic Technology""Using a holographic technology, the vacuum Improvement of performance such as "Creating method and its device", "Particle accelerator using holographic technology", "Method of transporting material at the time of machining holographic machine tool using holographic technology, and its device" Help. Also, by using the real image of the gravitational wave holography, it is possible to do everything about the material and the space. For example, for matter, if the focus of gravitational wave holography is coincident with the center of the atomic nucleus,
Since the nucleus is locked to the focus of the gravitational wave holography and cannot come off, moving the focus allows individual atoms to move and stop freely. Therefore, since a large number of atoms can be freely arranged in space, this becomes an ultra-high-precision “gravitational wave holography machine tool”. This gravitational wave holographic machine tool can work with any artificial workpiece. This gravitational wave holography machine tool can work at room temperature, so it is also possible to make a copy of a living body. Therefore,
This is not only a processing and repairing organ, but also a medical machine that creates individual organs as parts of a living body. In the gravitational wave holography machine tool, the space can be freely expanded and contracted by the free distribution of the gravitational focus by the gravitational wave holography. Therefore, it becomes a "gravitational wave holographic space processing machine". Since the gravity wave holographic space processing machine can freely expand and contract the space, it is possible to create a "compressed space" in which the space is compressed in a one-dimensional direction, and the compressed space can be used as transportation. In addition, a "two-dimensional compression space" or a "three-dimensional compression space (also a hollow plaque hole)" in which space is compressed in two-dimensional or three-dimensional directions can be created, and these can also be used as transportation. Thus, the use of the present invention allows all processing and movement of space and material. This means that the capabilities of the gravitational wave holography device can do anything related to "science of matter".

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing generation of a secondary spherical wave of a hole by a light beam.

FIG. 2 is a cross-sectional view showing generation of a spherical wave by a semiconductor laser array.

FIG. 3 is a cross-sectional view showing a holographic real image by a semiconductor laser array variable oscillation hologram.

FIG. 4 is a horizontal sectional view of a semiconductor laser array variable oscillation hologram bin having a cylindrical intermediate portion.

FIG. 5 is a cross-sectional view of a holographic fusion reactor bin using a semiconductor laser array variable oscillation hologram.

FIG. 6 is an enlarged sectional view of an upper portion of a holographic fusion reactor bin.

FIG. 7 is a detailed horizontal cross-sectional view in which the wall surface of the holographic fusion reactor bottle is enlarged.

FIG. 8 is a cross-sectional view of a power generation boiler in which a holographic fusion reactor bottle is housed in a tank and used as a heat source.

FIG. 9 is a principle diagram of generation of a gravitational wave by a pair of masses.

FIG. 10 is a cross-sectional view of a gemstone type bipolar gravitational wave generator in which two masses are rotated by a pair of mangled-type holographic split traveling multiple optical spheres / light shells.

FIG. 11 is a sectional view of a triangular gravitational wave generator in which three masses are rotated by three holographic division traveling multi-sphere optical shells and optical shells.

FIG. 12 is a horizontal sectional view of a holographic fusion reactor combined with gravity waves.

13A is a cross-sectional view showing a state of gravitational wave propagation by the bipolar gravitational wave generator. FIG. (B) It is a plan view of figure (a).

14A is a plan view showing a state of spherical gravitational wave propagation by a bipolar gravitational wave generator having a secondary rotation axis orthogonal to the center of the primary rotation axis. FIG. (B) A sectional view of FIG.

FIG. 15 (a) Mass M1 corresponding to spherical gravitational wave generation
It is a top view of the locus of (the mass M2 is on the opposite side of the center of the sphere). (B) It is a side view which shows the hemisphere of figure (a).

FIG. 16 is a detailed partial cross-sectional view of a gravitational wave hologram using a matrix of spherical gravitational wave laser elements.

FIG. 17 is a cross-sectional view of gravitational wave holography in which a conjugate focal real image is generated.

FIG. 18 is a cross-sectional view of gravitational wave holography in which a conjugate focal real image is not generated.

FIG. 19 is a sectional view of a gravitational wave holography apparatus.

[Explanation of symbols]

1 ……… Screen. 2 ... Hall. 3 ... Light flux. 4. Secondary spherical wave. 5 ……… The traveling direction of the secondary spherical wave. 6. Semiconductor laser element. 7 ...... Control circuit layer. 8 ……… Spherical wave of semiconductor laser. 9 Power wiring layer. 10 holographic laser. 11 ... Holographic real image. 12 ... Quartz glass bottle. 13… Semiconductor laser array variable oscillation hologram. 14 Light shell (split-progression multiple light shell BSNK). 15 ...... Support. 16 ...... Nuclear fuel injector end. 17 ... Nuclear combustion gas absorber end. 18 ...... Nuclear fuel injection direction. 19 ...... Nuclear combustion gas absorption direction. 20 ...... Electromagnetic wave energy generated by the nuclear fusion reaction. 21… Power mains (including insulator coating). 22 ....... Coating layer (gold as an example). 23 ...... Holographic fusion reactor bottle. 24 ............ Boiler tank. 25 ...... Nuclear fuel injector. 26 Nuclear combustion air inhaler. 27 ...... Nuclear fuel supply pipe. 28 ...... Nuclear combustion exhaust pipe. 29 ...... High temperature steam pipe. 30 ...... High temperature steam. 31 ...... Water supply pipe. 32 ...... Nuclear fuel supply direction. 33 Nuclear combustion exhaust direction. 34 ...... Tank support. 35 ...... Water supply. 36 ……… Flowing water direction. 37 ...... Tank top lid. 38 ... bolt a. 39 ... bolt b. 40 ...... Water surface. 41 ...... Power supply. 42 Wavefront of gravitational wave propagation. 43 …… Secondary rotation direction. 44 Secondary rotation axis (Y axis). 45 ……… Spherical gravity waves. 46 spherical spherical wave generating device (spherical gravity wave generating element). 47 ……… Gravitational wave holography gravitational wave laser. 48 ...... Ball structure. 49 ...... Real gravitational wave holography image generated outside the spherical structure. 50 Real-time gravitational wave holography image generated inside the spherical structure. H ...... Nuclear fuel. He: Nuclear combustion gas (gas or plasma). L1 Nuclear fusion generated light (generally electromagnetic waves). L2 ... transmitted light (generally electromagnetic waves). L3 reflected light (generally electromagnetic waves). D1 ... The thickness of quartz glass. D2 total thickness of the semiconductor laser element 6, the control circuit layer 7, and the power wiring layer 9. M1, M2, M3, M1 ', M2', M1 ", M2" ...
...... Each is a mass. v ...... Rotation speed. R ...... Rotation radius of circular orbit. φ ……… Diameter of mass. λ1 holographic laser of wavelength λ1 for holographic fusion reactor. λ2 holographic laser of wavelength λ2 for a gravitational wave generator. m ……… A gemstone type bipolar gravitational wave generator. BSNK …………. BSNK ': a split traveling multi-shell. H '... Fusion fuel plasma. X, Y, Z ... X axes orthogonal to each other,
Y axis, Z axis. k1, k2, k3,... k12 trajectories of the mass M1. k1 ', k2', k3 '... k12'... trajectories of the mass M1. R '… orbit radius on a spherical surface. Δd: The thickness of the gravitational wave hologram. F: Focused wave real image by gravity wave holography. F ′ ………………………………………………………………………………………………………………………………………………………………………………………………………………………………. O ...... The center of the sphere of the spherical gravitational wave hologram. $ 46 ...... Gravitational wave hologram.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification symbol FI H01S 3/103 H01S 3/103 (54) [Title of the Invention] Using a semiconductor laser array variable oscillation hologram bin using a semiconductor laser array variable oscillation hologram Gravitational wave combined holographic fusion reactor bin and method of gravitational wave holography and its apparatus.

Claims (44)

[Claims] 1. A method of a laser array variable oscillation hologram in which a large number of laser elements are arranged in a matrix and the whole is controlled by a control circuit, and an interference fringe pattern formed by light and dark of the oscillation and stop of the laser of the many elements is identified as a hologram. . 2. The method according to claim 1, wherein a semiconductor laser element is used as the laser element. 3. The method according to claim 1, wherein an electronic circuit is used for the control circuit. 4. The method according to claim 1, wherein an optical circuit is used for the control circuit. 5. The hologram is formed by calculation for displacing the phases of oscillation lasers of a large number of laser elements, wherein the hologram is formed. Variable oscillation hologram method. 6. The hologram according to claim 1, wherein the hologram is formed by calculation for synchronizing the phases of the oscillation lasers of a large number of laser elements. Variable oscillation hologram method. 7. A hologram with high device utilization efficiency without laser stoppage (stoppage means oscillation stoppage) by calculation based on a combination of phases and amplitudes of oscillation lasers of a large number of laser elements. A method of a variable oscillation hologram according to claim 5. 8. A variable oscillation hologram apparatus in which a large number of laser elements are arranged in a matrix and controlled by a control circuit, and an interference fringe pattern formed by light and dark of the oscillation and stop of the laser of the many laser elements is identified as a hologram. 9. The variable oscillation hologram device according to claim 8, wherein a semiconductor laser is used as the laser. 10. The variable oscillation hologram device according to claim 8, wherein an electronic circuit is used for the control circuit. 11. The variable oscillation hologram device according to claim 8, wherein an optical circuit is used for the control circuit. 12. The hologram is constructed by calculating a displacement of a phase of an oscillating laser of a plurality of laser elements, wherein the hologram is constituted by a calculation. Variable oscillation hologram device. 13. A hologram is formed by calculation for synchronizing the phases of oscillation lasers of a large number of laser elements, wherein the hologram is constituted by a calculation. Variable oscillation hologram device. 14. The hologram according to claim 12, wherein a hologram having a high device utilization efficiency without stopping the laser is formed by a calculation based on a combination of phases and amplitudes of oscillation lasers of a large number of laser devices. Variable oscillation hologram device. 15. A variable semiconductor laser array in which a large number of semiconductor laser elements are arranged in a matrix and the whole is controlled by a control circuit, and an interference fringe pattern formed by light and dark of the oscillation and stoppage of the laser of the large number of semiconductor laser elements is identified as a hologram. Oscillation hologram. The semiconductor laser array variable oscillation hologram, its control circuit layer, and the power wiring layer are installed in the shell-shaped container, and the holographic split traveling multiple light shell is formed in the inner space of the container by the operation of the semiconductor laser array variable oscillation hologram. A variable oscillation hologram bin for a semiconductor laser array. 16. The variable oscillation hologram bin according to claim 15, wherein a variable oscillation hologram semiconductor laser array, a control circuit layer, and a power wiring layer are provided outside the container. 17. The variable oscillation hologram bin according to claim 15, wherein a variable oscillation hologram semiconductor laser array, a control circuit layer, and a power wiring layer are provided inside the container. 18. The semiconductor according to claim 15, 16 or 17, wherein the container is formed by narrowing both ends of a cylindrical shape to form a conical shape of an hourglass. Laser array variable oscillation hologram bin. 19. The method according to claim 15, wherein the container is formed of a spherical shape.
8. The variable oscillation hologram bin of the semiconductor laser array according to claim 7. 20. The container according to claim 15, wherein the container is made of a transparent material.
Item 21. The variable oscillation hologram bin of the semiconductor laser array according to item 19. 21. The container according to claim 15, wherein the material of the container is made opaque.
Item 20. The semiconductor laser array variable oscillation hologram bin according to Item 8 or Item 19. 22. A variable oscillation hologram bin according to claim 20, wherein quartz glass is used as a material of the transparent container. 23. The method according to claim 15, wherein the inside of the semiconductor laser array variable oscillation hologram is blackened to improve the efficiency of absorbing heat generated by the reaction.
Terms, 16, 16, 17, 18, 19, 20
23. The variable oscillation hologram bin of the semiconductor laser array according to item 21, item 21 or item 22. 24. An observation image inside the container is taken out as an electronic image by using each laser element of the variable oscillation hologram of the semiconductor laser array or an element separately arranged adjacently as a light receiving element. Range 1
5, 16, 17, 17, 18, 19, 2
24. The variable oscillation hologram bin of a semiconductor laser array according to any one of paragraphs 0, 21, 22, and 23. 25. A variable semiconductor laser array in which a large number of semiconductor laser elements are arranged in a matrix and the whole is controlled by a control circuit, and an interference fringe pattern formed by light and dark of the oscillation and stop of the laser of the many semiconductor laser elements is identified as a hologram. Oscillation hologram. The semiconductor laser array variable oscillation hologram, its control circuit layer and the power wiring layer are installed in a container, and the semiconductor laser array variable oscillation hologram is actuated to form a holographic split traveling multiple light shell in the inner space of the container. Laser array variable oscillation hologram bin. A holographic split traveling multi-beam shell is formed in the interior space using the semiconductor laser array variable-oscillation hologram bin, and the fusion fuel sent from one end of the bin is confined inside the light shell to make it extremely hot. The fusion reaction is made into plasma, and then the thermal energy generated by the fusion reaction becomes electromagnetic radiation and reaches the inner wall of the bottle, efficiently penetrates the energy and reaches the outer wall of the bottle, and the outer wall of the bottle and the inner wall of the tank Holographic fusion reactor bin method for generating steam for power generation by being absorbed in distilled water during the period. 26. A variable semiconductor laser array in which a plurality of semiconductor laser elements are arranged in a matrix and the whole is controlled by a control circuit, and an interference fringe pattern formed by light and dark of the oscillation and stop of the laser of the many semiconductor laser elements is identified as a hologram. Oscillation hologram. The semiconductor laser array variable oscillation hologram, its control circuit layer and the power wiring layer are installed in a container, and the semiconductor laser array variable oscillation hologram is actuated to form a holographic split traveling multiple light shell in the inner space of the container. Laser array variable oscillation hologram bin. A holographic split traveling multi-beam shell is formed in the interior space using the semiconductor laser array variable-oscillation hologram bin, and the fusion fuel sent from one end of the bin is confined inside the light shell to make it extremely hot. The fusion reaction is made into plasma, and then the thermal energy generated by the fusion reaction becomes electromagnetic radiation and reaches the inner wall of the bottle, efficiently penetrates the energy and reaches the outer wall of the bottle, and the outer wall of the bottle and the inner wall of the tank A holographic fusion reactor bin device that generates steam for power generation by being absorbed in distilled water during the period. 27. A variable semiconductor laser array in which a large number of semiconductor laser elements are arranged in a matrix and the whole is controlled by a control circuit, and an interference fringe pattern formed by light and dark of the oscillation and stop of the laser of the many semiconductor laser elements is identified as a hologram. Oscillation hologram. The semiconductor laser array variable oscillation hologram, its control circuit layer and the power wiring layer are installed in a container, and the semiconductor laser array variable oscillation hologram is actuated to form a holographic split traveling multiple light shell in the inner space of the container. Laser array variable oscillation hologram bin. Using the semiconductor laser array variable oscillation hologram bin, a holographic split traveling multi-shell is formed in the inner space, and the holographic split progressive multi-shell and a substance enclosed in the container (mass The most suitable element is iron, which is the most stable element that is unlikely to cause a nuclear reaction upon compression.) The gravitational wave generator consisting of the compressed mass and the pressure of the holographic split traveling multiple light shell is formed. Using the gravitational wave generator and the attractive force of the gravitational wave generator together, the fusion fuel sent from one of the mouths of the bottle is confined inside the light shell and turned into ultra-high temperature plasma to cause a fusion reaction. Next, the heat energy generated by the fusion reaction reaches the inner wall of the bottle as electromagnetic radiation, efficiently penetrates the energy, reaches the outer wall of the bottle, and is absorbed by distilled water between the outer wall of the bottle and the inner wall of the tank. A method for a holographic fusion reactor bin with gravitational waves, characterized by generating steam for power generation. 28. One or two or more gravitational wave sources that are generated and propagated in a donut shape by a gravitational wave generator having only one primary rotation in which two masses are rotated in the same direction at 180 degrees on a circular orbit. 28. The method for a holographic fusion reactor bin with gravitational waves according to claim 27, wherein the gravity of the holographic fusion reactor is utilized. 29. Addition of two masses to a primary rotation rotated in the same direction at 180 degrees on a circular orbit, and about a secondary axis centered and orthogonal to the primary axis of the primary rotational circular orbit. A gravitational wave source generated and propagated in a spherical shape by a spherical gravitational wave generator having a secondary rotation for rotating the two masses, and one or more gravitational wave sources are arranged and the attraction is used. 28. The method of a holographic fusion reactor bin with gravitational waves according to claim 27. 30. A variable semiconductor laser array in which a large number of semiconductor laser elements are arranged in a matrix and the whole is controlled by a control circuit, and an interference fringe pattern formed by light and dark of the oscillation and stop of the laser of the many semiconductor laser elements is identified as a hologram. Oscillation hologram. The semiconductor laser array variable oscillation hologram, its control circuit layer and the power wiring layer are installed in a container, and the semiconductor laser array variable oscillation hologram is actuated to form a holographic split traveling multiple light shell in the inner space of the container. Laser array variable oscillation hologram bin. Using the semiconductor laser array variable oscillation hologram bin, a holographic split traveling multi-shell is formed in the inner space, and the holographic split progressive multi-shell and a substance enclosed in the container (mass The most suitable element is iron, which is the most stable element that is unlikely to cause a nuclear reaction upon compression.) The gravitational wave generator consisting of the compressed mass and the pressure of the holographic split traveling multiple light shell is formed. Using the gravitational wave generator and the attractive force of the gravitational wave generator together, the fusion fuel sent from one of the mouths of the bottle is confined inside the light shell and turned into ultra-high temperature plasma to cause a fusion reaction. Next, the heat energy generated by the fusion reaction reaches the inner wall of the bottle as electromagnetic radiation, efficiently penetrates the energy, reaches the outer wall of the bottle, and is absorbed by distilled water between the outer wall of the bottle and the inner wall of the tank. An apparatus for a holographic fusion reactor bin with gravitational waves, characterized by generating steam for power generation. 31. One or two or more gravitational wave sources that are generated and propagated in a donut shape by a gravitational wave generator having only one primary rotation in which two masses are rotated 180 degrees in a circular orbit in the same direction are arranged. 31. The apparatus for a holographic fusion reactor bottle with gravitational waves according to claim 30, wherein the attraction force is utilized. 32. In addition to the primary rotation in which two masses are rotated in the same direction at 180 degrees on a circular orbit, the two masses are rotated around a secondary axis that is orthogonal to the primary axis of the primary rotating circular orbit. A gravitational wave source generated and propagated in a spherical shape by a spherical gravitational wave generator having a secondary rotation for rotating the two masses, and one or more gravitational wave sources are arranged and the attraction is used. 31. An apparatus for a holographic fusion reactor bin with gravitational waves according to item 30. 33. A variable semiconductor laser array in which a large number of semiconductor laser elements are arranged in a matrix and the whole is controlled by a control circuit, and an interference fringe pattern formed by light and dark of laser oscillation and stop of the large number of semiconductor laser elements is identified as a hologram. Oscillation hologram. The variable oscillation hologram of the semiconductor laser array, its control circuit layer and the power wiring layer are installed, and the operation of the variable oscillation hologram of the semiconductor laser array causes the holographic division traveling multi-shell to be compressed into the space (the most suitable mass as the mass). The element is iron, which is the most stable element that is unlikely to undergo a nuclear reaction upon compression.) To form a gravitational wave generator. Two masses are added to the primary rotation rotated 180 degrees in the same direction on a circular orbit, and the center is orthogonal to the primary axis of the primary rotational circular orbit.
A number of spherical gravitational wave generating elements to which the two masses are rotated around the secondary axes are arranged in a matrix on the surface, and the secondary axes of the elements are aligned in the same direction. A method of gravitational wave holography in which an interference fringe pattern formed by oscillating and stopping spherical gravitational waves due to rotation and stopping of a large number of spherical gravitational wave generating elements is identified in a hologram. 34. The method for gravitational wave holography according to claim 33, wherein the spherical gravity wave generating elements are arranged on a curved surface. 35. The gravitational wave holography method according to claim 33, wherein the spherical gravity wave generating elements are arranged on a spherical surface. 36. A variable oscillation hologram bin in which a semiconductor laser array variable oscillation hologram, a control circuit layer, and a power wiring layer are provided outside a shell-shaped container. Item 34, Item 34 or Item 35, The method of gravitational wave holography. 37. The method according to claim 33, wherein a semiconductor laser array variable oscillation hologram bin in which a semiconductor laser array variable oscillation hologram, a control circuit layer, and a power wiring layer are provided inside the shell-shaped container. Item 34, Item 34 or Item 35, The method of gravitational wave holography. 38. The method according to claim 33, wherein the shell-shaped container is a spherical shell-shaped container.
40. The method of gravitational wave holography according to claim 5, 36 or 37. 39. A variable semiconductor laser array in which a large number of semiconductor laser elements are arranged in a matrix and the whole is controlled by a control circuit, and an interference fringe pattern formed by light and dark of the oscillation and stop of the laser of the many semiconductor laser elements is identified as a hologram. Oscillation hologram. The variable oscillation hologram of the semiconductor laser array, its control circuit layer and the power wiring layer are installed, and the operation of the variable oscillation hologram of the semiconductor laser array causes the holographic division traveling multi-shell to be compressed into the space (the most suitable mass as the mass). The element is iron, which is the most stable element that is unlikely to undergo a nuclear reaction upon compression.) To form a gravitational wave generator. Two masses are added to the primary rotation rotated 180 degrees in the same direction on a circular orbit, and the center is orthogonal to the primary axis of the primary rotational circular orbit.
A number of spherical gravitational wave generating elements to which a secondary rotation that rotates the two masses around the secondary axis are added are arranged on the surface, and the secondary axes of the elements are aligned in the same direction, and the A gravitational wave holography apparatus in which an interference fringe pattern formed by oscillating and stopping spherical gravitational waves due to rotation and stopping of a number of spherical gravitational wave generating elements is identified in a hologram. 40. The gravitational wave holography apparatus according to claim 39, wherein the spherical gravitational wave generating elements are arranged on a curved surface. 41. The gravitational wave holography device according to claim 39, wherein the spherical gravitational wave generating elements are arranged on a spherical surface. 42. A variable oscillation hologram bin for a semiconductor laser array in which a semiconductor laser array variable oscillation hologram, a control circuit layer, and a power wiring layer are provided outside a shell-shaped container. Item 40, Item 40, or Item 41. 43. A variable oscillation hologram bin in which a semiconductor laser array variable oscillation hologram, a control circuit layer, and a power wiring layer are provided inside a shell-shaped container. Item 40, Item 40, or Item 41. 44. The method according to claim 39, wherein the shell-shaped container is a spherical shell-shaped container.
Item 44. The apparatus for gravitational wave holography according to Item 1, 42 or 43.