WO2014121524A1 - Method for implementing quantum computer, quantum communication, and bare-eye 4d holographic television system - Google Patents

Abstract

The present invention relates to the field of a quantum computer, quantum communication, and bare-eye 4D holographic image display. Disclosed is a method for implementing a quantum computer, quantum communication, and a 4D holographic television system. To replace conventional NTSC, PAL, and SECAM modes with a rapid and accurate quantum communication method for transmitting image information and displaying a holographic image on a TFTLCD, a method for quantum computation, quantum communication, and television image display is provided, which is different from a conventional quantization principle. To achieve the purpose, the present invention creates, on the basis of a Liu's partition equation, a quantization equation, a binocular parallax equation, and a quantum state coupling equation used for generating a quantum entangled state and dividing a visual spectrum into three sub-color gamuts for parallel data processing; therefore, the image processing, transmission efficiency, and 4D display effect are significantly improved, and the cost is lowered. The present invention disclaims the classical uncertainty relationship and quantum state non-cloning theorem, and clears obstacles for technical implementation of a 4D bare-eye television system based on a quantum computer and quantum communication.

Description

 A method for realizing quantum computer quantum communication and naked-eye 4D holographic television system 1. Technical field: It belongs to the field of display technology of quantum computer, quantum communication and naked-view 4D holographic image.

Second, the background art: Quantum communication and naked-view 4D TV are widely concerned technical fields, but so far, the technology of constructing multi-qubit computing networks and the technique of correcting decoherence are still immature, and quantum computing methods have not been broken. Therefore, the practical application of quantum communication is hindered; closely related to quantum communication technology is 3D and the 4D TV technology of the present invention. So far, cheap and practical naked-view color televisions have not entered thousands of households, and home televisions still It is mainly because of the wearing of visual aids. However, users are less and less interested in wearing TVs for watching TVs. Television images are visual products that are closely related to visual psychology for visual viewing. The final arbitration must be made by the human eye, and the NTSC, PAL and SECAM modes for transmitting analog TV signals deviate significantly from the image fidelity principle, which is forgiven for the average TV user, but for medical images, interstellar communication images. That is, it is a big problem that cannot be ignored; with traditional NTSC, PAL and S ECAM system also has the disadvantages of large amount of data and limited bandwidth. With the rapid development of multimedia TV technology, there are more and more types of image output devices, and image processing speeds obviously have bottlenecks. Therefore, quantum computing logic, Quantum communication technology and image multi-dimensional display technology have become an urgent need. The goal of the present invention is to comprehensively solve the difficulties encountered by the three cross-over technologies, and to create a practical and inexpensive one that can be accepted by users. The 4D TV system, supported by quantum computing and quantum communication technology, can greatly improve image processing, transmission efficiency and display quality of multi-dimensional images, but the cost is reduced, and it can achieve multiple effects.

The present invention is a continuation of our published application Ser. No.: WO/2012/116468, Application No. PCT/CN2012/073178, and PCT/CN2011/001729, each of which is incorporated herein by reference. There is a close relationship.

Third, the content of the invention

 1. Quantumized light wave tristimulus value XYZ method

Purpose: The traditional TV image communication method uses NTSC, PAL, SECAM as the tools to transmit the RGB signals captured by the camera to the receiving end. In order to fundamentally overcome the drawbacks of the traditional system, the present invention uses quantum computing and quantum communication. The method transmits and calculates prgb 4-dimensional color image information. The first key technology involved is to express the three-excited value XYZ of the object light wave into quantum bit information.

1) What is quantum information:

In order to achieve the purpose of quantum communication, the present invention firstly displays the triple-excited data XYZ from the object light wave by quantum information, and uses the quantum bit as a basic quantity for calculating, transmitting, and displaying a 4-dimensional color image.

The fundamental difference between quantum information and classical information is: Classic information is represented by a binary string consisting of binary 0 or 1. Its information unit is called "bit". Unlike classical information units, quantum information is described in quantum language. When the "qubit" is used as the information unit, and the string consists of the state | 0> and the state | 1>, the symbol | 〉 is called the Dirac symbol, and for the classic photon, it can only be in the | 0> Or one of the states, the quantum information is different, and the objects involved are microscopic particles, such as photons, electrons, protons, neutrons, etc., because the microscopic particles have wave-particle duality, so the quantum information is The two elements of classical information and quantum information, the information unit of quantum information is represented by the symbol | ψ>, and is called "qubit bit". The information with "bit" as the information unit is classical information, if "quantum bit""As a unit of information, then "information" is quantized into a quantum state; the difference between a quantum state particle and a classical particle is: after the separation of two classical particles De-correlation, the case of quantum particles is different. Regardless of the spatial separation, there are still quantum correlations between the two particles. That is, quantum is said to be in an entangled state, and the effect exerted on one of the particles will inevitably affect its entanglement. Another particle, the operation of generating and processing entangled states is the core method of quantum science. The purpose of quantization is to use this entangled state to accomplish tasks that classical information cannot accomplish independently. Assuming that two particles are quantum pairs in an entangled state, the entangled states of the two particles are described in quantum mechanics using the following model: Please note: Because some of the symbols used in quantum science, such as the Dirac symbols mentioned above, are not familiar to most engineering and technical personnel, the use of these symbols does not help to quickly grasp and understand the essence of quantum science, and is even more helpless. In order to understand and grasp the present invention, the present invention adheres to the purpose and objective of "industrial practicality", avoids difficult theoretical explanations, and does not use the Dirac symbol, in order to obtain an effect that can be practical immediately.

In the visible spectrum, any color can be quantified by the light oscillating value XYZ, which is a standard data obtained by linear conversion of three primary colors r, g, b, involving three basic particles of red, green and blue. The complex entanglement relationship, how to clarify this entanglement relationship and establish the quantization equation of the three-excited value XYZ is one of the key steps in the quantization of XYZ.

 2. Quantumized light wave tristimulus value XYZ method

Purpose: The present invention uses quantum computing and quantum communication methods to transmit and calculate p-rgb four-dimensional color image information. The first key question involved is: How to express the three-excited value XYZ of the object light wave into information represented by quantum bits. .

 1) What is quantum information:

 At the end of 1900, Planck discovered that the energy of the vibrating charged particles can only be an integer multiple of a certain minimum energy value ε. This indefinite minimum energy ε is called quantum, which is a tiny unit that can be counted one by one. Therefore, quantum communication can be said to communicate in a certain quantum information unit. In order to achieve the purpose of quantum communication, it is necessary to express the triplet value of the object light wave with quantum information, and then use the quantum bit as the basis for calculating, transmitting and displaying the four-dimensional color image.

The fundamental difference between quantum information and classical information is: Classic information is represented by a binary string consisting of binary 0 or 1. Its information unit is called "bit". Unlike classical information units, quantum is based on "quantum bits". Information unit. The objects involved in quantum information are microscopic particles, such as photons, electrons, etc. Because microscopic particles have wave-particle duality, quantum information is composed of two kinds of classical information and quantum information, if "quantum bits" are used as information. Unit, then "information" is quantized into a quantum state; the difference between a quantum state particle and a classical particle is: two classical particles are lost after separation, and the quantum particle is different, regardless of spatial separation, two There is still a quantum correlation in the particle, that is, quantum is said to be in an entangled state. The effect exerted on one of the particles will inevitably affect another particle entangled with it. The operation of generating and processing the entangled state is the core method of quantum. The purpose of quantization is to use this entangled state to accomplish tasks that classical information cannot accomplish independently.

In the visible spectrum, any color can be quantified by the light wave triple 剌 ,, which is the standard data obtained by linear conversion of the three primary colors r, g, b, involving three basic particles of red, green and blue. The entanglement relationship, how to clarify this entanglement relationship and establish the quantization equation of the three-excited XYZ is one of the key steps in the quantization of XYZ.

 2) Preliminary steps to generate an unknown quantum state

The light wave signal taken by the CCD TV camera is represented by the data of the RGB color space. Since the display devices used in TV, computer or mobile phone work in the CIE XYZ color space, the RGB color is used to use the matrix equation below. Data conversion becomes data expressed in XYZ:

The invention starts with the XYZ data as the original data. The traditional understanding is: the three-shot XYZ obtained by the CCD camera records the red, green and blue stimuli of the object light wave, belonging to the two-dimensional plane image data. In fact, this traditional statement is not correct. The XYZ from the CCD camera contains not only the intensity information of the light wave but also the phase information. The reason why the present invention is to quantum the light wave signal captured by the CCD camera. The purpose of the processing is to extract the qubit information of the image signal from the XYZ, including the intensity and phase information, and then transmit and display the qubit information to return the image signal to the "wave-particle duality" true colors.

 3) Preparing the entangled state for the unknown quantum state XYZ - Normalize the XYZ with the Liu's segmentation equation:

Intuitively, in an established white lighting environment, when an observer observes an object against a black background, the observer deals with quantum problems in a positive space, and conversely, if the observer is observing an object against a white background. Then the observer is dealing with quantum problems in the anti-space. According to the quantum point of view, when the CCD camera is used to capture and output the three-shot XYZ of the light wave, because the object light wave contacts the CCD original, that is, the macroscopic object is touched, and the object light wave suddenly appears "wave packet collapse" phenomenon. , three 剌 剌 XYZ only records the particle information of photons, and loses the volatility information therein. However, the present invention believes that: 剌 剌 剌 ΧΥΖ is an "unknown quantum state" in quantum science, not after the light wave contacts the CCD component. After the wave packet collapses, after the light wave enters the CCD crystal, the photon fluctuation information is quickly hidden behind the particle information because it is decomposed into transmissive and refractive components. Appropriate measures are taken. It can make the original "invisible" wave information exposed to the original shape, and achieve the purpose of accurately quantizing XYZ.

 (1) Method for normalizing unknown quantum state XYZ in positive space - Liu's positive space partition equation

The present invention regards the three-excited value XYZ of a pixel as an unknown quantum state, because its quantum bit information is unknown, and the first step of quantizing the triple-excited value XYZ is to use the Liu's segmentation equation for the triple-excitation value XYZ. Pretreatment is performed. In our patent application with the application number PCT/CN2011/000327 PCT application, WO2012/116468 ZH 2012.09.07, a sub-invention called the Liu's segmentation equation is given, which we will use in the present invention. The Liu's partition equation preprocesses the unknown quantum state XYZ, thereby extracting four kinds of data such as white amount data _Pu and primary color quantities r _u , g _u , b _u from XYZ, but we do not transmit them as television signals. We only use the parameters r _u , g _u , b _u as the original parameters of the phase information of the light wave of the object, and the parameters transmitted to the receiving end are only the data of the white quantity p _u and the phase angle ,, by means of the white quantity _Pu and the phase informationΘ Indirect transmission of the three primary colors XYZ is one of the features of the present invention. The Liu's segmentation equation is a preprocessing tool for segmenting XYZ. The final "qubit" expression cannot be obtained, but it can evolve more intuitive and convenient quantization parameters because the visible spectrum is a wavelength. The colored light strips arranged in order can be divided into three bands of high frequency, intermediate frequency and low frequency. The Liu's segmentation equation divides this complete color space into three sub-color spaces, which are respectively p _u g _u b _u subspaces. , p _u g _u b _u subspace and p _u g _u b _u subspace, for the same set of three 剌 XYZ, are described in different subspaces with incomplete argument parameters:

In the Ρ^Λ subspace, the self-change: : The parameters are Ρ _υ , and 13⁄4 _:

X = [(1-g _u )(1-0 _u )X , +g _u ^-b _u )X _g +b _u ^-g _u )X _b +g _u b _u X _c }^-p _w ) + p _w X _w

Y = [(1— g _u )(1— 0 _u )Y + g _u ^-b _u )y _g +b _u ^-g _u )Y _b +g _u b _u y _c ^-p _w ) + p _w y _w

Z = [(1-g _u )(1-0 _u )Z, + g _u ( -b _u )Z _g +b _u ( -g _u )Z _b + g _u b _u Z _c ]·(1-ρ .) + p _w Z _w

In the ^ subspace, the argument: number [is pP _uU , , and 0„:

x = [(i- (i-0 _u )x _tec r _u ^-b _u )X _{r +} b _u ^-r _u )X _{b +} r _u b _u X _m ].^-p _w ) ₊ p _w X _w

γ=[(ι— (1— 0 _u )v _ad( + ^'-b _u )Y _{r +} b _u ( r _u )Y _{b +} r _u b _u Y _m ( p _w ) ₊ p _a Y _a

Z = [( r _u )( b _u )Z _back -b _u )Z _r +b _u (\- r _u )Z _b + r _u b _u Z _m ]-(1-p + p _w in space: , The argument parameters are p _u , ^ and ^

The above Liu's segmentation equation is a combination of equations composed of three 3-ary quadratic equations. The left end of each equation group is the triple-spot value of the same pixel captured by the CCD camera, in quantum language, each The left end of a system of equations is an unknown quantum state represented by XYZ, and the right end is composed of two parts. In the visual spectral range, each equation group divides the color XYZ into a color component and a white component. The former is proportional. a color component of (1 p _w ), the latter being a white component of the ratio p _w ; the Liu's segmentation equation divides the color in the visual spectrum into three segments in increasing order of wavelength, using the first equation to describe the short wave region All colors XYZ, which are colors synthesized by the additive method of the green primary color g _u , the blue primary color b _u and the white amount p _w , which can be classified as p _w g _u b _u sub-gamut Color; use the second system of equations to describe all the colors in the medium wave region. These are the colors synthesized by the additive method of the red primary color r _u , the blue primary color b _u and the white amount p _w , so the color in this segment is returned. Class is p _w r _u b _u sub-gamut color; the third system of equations describes all colors in the long-wavelength region, which are some of the colors synthesized by the additive process of the red primary color r _u , the green primary color g _u and the white quantity _Pw , so Within this section The color is called the color of the p _w r _u g _u sub-gamut. The three-shot stimuli [X _back . _k , Yback-k, Z _baek . _k ] represent the measured three-shot stimuli of the background color of the normally black display, and the three-shot stimuli [X _back .w, Yback-w, Z _baek . _w ] represents the measured triple 剌 value of the background color of the normally white display, and the triple 剌 excimer [X _w , Y _w , Z _w ] represents the triple 剌 value of the isochromatic white light synthesized by the equal amount of three primary colors, generally It is stipulated that it is equal to the three-intensity value of the standard D ₆₅ illumination. Of course, other standard white light triple-excitation values can be used as needed. That is to say: 1 unit of red light plus 1 unit of green light, and then Adding 1 unit of blue light, the result is 1 unit of white light, which leads to a conclusion: When adding white light by equal amount of three primary colors, the binary coding law of quantum computer is followed; The excitatory values [ , Y _r , Z _r ], [X _g , Y _g , 3⁄4], [X _b , Y _b , Z _b ] are respectively red when the standard color temperature white light [X _w , Y _w , Zw] is synthesized. , green, and blue color value of three stimulation, the color units are defined as the amount of each primary _{color, [X c, Yc, Z} [X m, Y m, Z m], [X y, Y y Z _y] represent the cyan, magenta, and yellow three stimulation values, etc. which are capable of [blue + green], [Red + Blue], [red + green] adding unit primary color between color composition That is to say, one unit of green light plus one unit of blue light generates one unit of cyan light, and one unit of red light plus one unit of blue light generates one unit of magenta light. One unit of red light plus one unit of green light produces one unit of yellow light, which leads to a conclusion: When synthesizing the inter-color with the three primary colors, the binary encoding of the classic computer is followed. Regularity, it can be seen that: The collection of all colors on the spectrum follows the quantum coding law of binary and binary exchange.

Please pay special attention to the fact that the invention provides: three-shot excitability values [X _back -k, Yback-k, Z _back . _k ], [Xback-w, Yback-w, Z _back . _w ], [X„, Y„, Z _w ], [X _r ,

Yr, Z _r ], [X _g , Y _g , 3⁄4], [X _b , Y _b , Z _b ], [Xc, Yc, Z [X _m , Y _m , Z _m ], [X _y , Y _y , Z _y ] and other 9 sets of triple-excitation values are 9 sets of known standard data shared by the transmitting end and the receiving end, which are called data states in quantum; [ _Pp X _w , PpYw, p _P Z in the Liu's partition equation _w ] represents the triplet value of the white amount p _w =1, the purpose of which is to automatically extract the amount of white contained in the unknown quantum state XYZ using the data [p _w X _w , PwYw, p _w Z _w ], 9 sets of data The state and the automatic extraction of the white amount by the Liu's segmentation equation actually provide an available intersection for the shooting space and the display space. According to the quantum theory, the shooting and display space is two parallel spaces, and the data state formed by the intersection It is convenient for the realization of "time-space crossing" for the unknown quantum state. By solving the Liu's partition equation, the quantum states of four quantum parameters, such as the primary color quantities r _u , g _u , b _u and the white quantity p _w , can be obtained in three sub-gamuts, which is a quantization of the unknown quantum state XYZ. The key step, the function of the Liu's segmentation equation is similar to the Liu's primary color clamp equation given in our publication, Pub. No.: WO/2012/116468, which is actually a clamp equation, by Liu. The clamping process of the segmentation equation also causes p _w , r _u , g _u , b _{u to} be normalized to quantum segmentation data between 0 and 1, thereby creating the necessary and sufficient conditions for establishing the Liu's quantization equation.

 (2) Method for normalizing the unknown quantum state XYZ in inverse space - Liu's inverse space partition equation

The liquid crystal display has two basic working modes: normal white and normal black. The display operating in the normally white state, such as the display of computer and mobile phone, adopts the normally white working mode, which is exactly the working mode of the television display. On the contrary, if the working color space of the normally black display is called the positive color space, the normally white display works in the inverse color space. When the XYZ is pre-quantized in the inverse color space, the following is required. Anti-space Liu's partition equation:

The difference between the inverse space Liu's partition equation and the aforementioned positive space Liu's partition equation is that the background color of the display is derived from the black three-shot value.

[Xback-k, Yback-k, Z _back . _k ] becomes white triple shock value [X _back . _w , Yback-w, Z _bac kw], meaning of other parameters and sub-invention 1-3)-(1) The meaning is exactly the same, the three 剌 值 [Xbaek-w, Yback-w, Zbaek.w] and the aforementioned three 剌 值 [Xbaek.k, Yback-k,

[Xback-w, Yback-w, Zback-w] [Xw, Yw, Z _w ], [X _r , Yr, Z _r ], [Xg, Yg, Zg], [Xb, Yb, Zb], [Xc , Y"Z(;), [X _m , Ym, Z _m ], [Xy, Yy, Zy] are identical, Conclusion: Set 9 standard data states and 4 kinds of r _u , g _u , b _u , _Pw The quantum state of the quantum parameter is a unique method of the "space-time crossing" power provided by the present invention for the unknown quantum state XYZ.

 4) Method of quantifying unknown quantum states in positive space XYZ method - Liu's quantized positive equation

Purpose and use:

Both the positive and negative equations of Liu's quantization involve quantum entangled state generation techniques and sub-gamut segmentation techniques. The entangled state and sub-gamut segmentation techniques are used to realize the parallel processing technology of quantum computing. The technology of entangled state and sub-gamut segmentation can Improve image processing, transmission efficiency and display quality of multi-dimensional images, but the cost is reduced. The basis of p _w , r _u , g _u , b _u calculated by Liu's partition equation can evolve the Liu's quantum as shown below. Equation:

The format of Liu's quantized positive equation:

The purpose of quantization is to represent the unknown quantum state XYZ as a format expressed in qubits, reflecting the wave-particle duality, state coexistence and other quantum properties of XYZ, changing the Liu's segmentation equation given by sub-invention 1. In the following format, it becomes the positive space Liu's quantization equation:

Α Α space: = (y + ² ) ^1/2 , tge = bg _u

Sin 0 = Y R, ∞s Θ, cos 9 = Y R

= [ _back - _k si (1 - R cose) + X _b sin- ¹ Θ + Χ ₀ cos- ¹ ^](1-p _w ) + p _w X _w

' y = [y _back - _k sin^)(1― R cose) + Y _b sin- ¹ Θ + Υ ₀ cos- ¹ ^](1-p _w ) + p _w Y _w

Z = [Z _back _ _k (1-R sin^)(1 - R cose) + Z _b sin- ¹ 0 + Z _c cos- ¹ e]( -p _w ) + p _w Z _w

In / Λ subspace: R = (v _r ² +Y _m ² , tg θ = rb _u

= [ _back - _k sin^)(1 - R cose) + X _r sin- ¹ 6 + X _m cos- ¹ ^](1-p _w ) + p _w X _w

' y = [y _back - _k sin^)(1― R cose) + Y _r sin- ¹ 0 + Y _m cos- ¹ ^](1-p _w ) + p _w Y _w

Z = [Z _back _ _k (1 - R sin6')(1 - R cosd) + Z _r sin" ¹ & + Z _m cos - ¹ 6>](1-p _w ) + p _w Z _w

In the p _u g _u subspace: R = ( + † , tg g _u

In the Liu's quantization equation, [p _w X _w , p _u Yw, p _u Z _w ] is the classical information part of the qubit, and the white quantity p _w shows the particle property of the object light wave XYZ. In quantum science, classic information is information that can be acquired by measuring the amount of white in the present invention, the unit is set to three stimulation value of the standard illumination, such as a standard light source D65 value of three stimulation _{[Xw, Yw, Z w]} , whereby easy, Accurately calculate the white amount _Pw , of course, other color temperature data can be selected according to different needs. At the right end of the Liu's quantization equation is the quantum information. The polynomial in front of the plus sign is the quantum information component of the quantum bit. The phase angle Θ is calculated indirectly by using the already calculated ^ g _u , b _u data. And the cosine value clearly expresses the wave property of the object light wave XYZ. The information represented by the classical information part and the quantum information part is constructed in a complementary relationship by the white quantity parameters p _w and (1 p _w ), as long as the p _w data is calculated. I also know other colors. The amplitude of the color photon (1 - p _w ) _; further observation of the Liu's quantization equation shows that the white photon also passes (1 - Rsin ) (1 - Rcos and background light p _k . _k Yb _ack . _k Z _back . _k ] Or [X _back . _w Y _back . _w Z _back . _w ] generates an entangled state. It can be seen that the Liu's quantization equation gives a total of nine entangled states and forms multiple qubits. The Liu's quantization equation can be accurate. The description of the "wave-particle duality" of microscopic particles. Microscopic particles also have the characteristics of "tunnel crossing". The Liu's quantization equation also describes the "tunnel crossing" characteristic, for example: red photons can traverse between sub-gamuts The barriers from the p _w r _u g _u subspace into the p _w r _u b _u subspace and the p _w g _u b _u subspace, due to the "tunnel crossing" property of the microscopic particles, so that the quantum information is identically entangled The state exists in two different subspaces and exhibits the "state coexistence" feature.

 3. The method of determining the space of the quantum by "observation":

Assuming that the white amount p _{w is} divided into 324 steps according to a certain step, which means that the gray level of the image is 324, then the unknown quantum can be determined by comparing the relative sizes of the normalized three-shot XYZ. The subspace where XYZ is located, the specific practices and steps are as follows:

(1) Dividing the three-excitation values X, Y, and Ζ by (Xw+Y _w + Zw), respectively, and normalizing them to X. , Y. And Z. ;

(2) Compare the three-magnitude X with the large-selective small logic circuit. , Y. And Z. The relative size of the difference is found in the maximum and minimum values, and the maximum and minimum values are used to determine the subspace in which the three stimuli X, Y and Z are located, unless they are at X. =Y. =Z. The state can always be compared to the relative size, even in Χ. =Υ. =Ζ. The state, which is nothing more than a neutral gray, does not destroy the rules described here;

(3) If X. The values are the minimum and Ζ. The value is the maximum value, then the unknown quantum state is in the p _w g _u b _u subspace. The white quantity _Pw and the primary color component contained in X, Y and Z should be calculated using the p _w g _u b _u type Liu's partition equation. The values of g _u and b _u ;

(4) If Y. The value is the minimum and X. The value is the maximum value, then the unknown quantum state is in the p _w " _u bu subspace. The p _w " _u bu type Liu's partition equation should be used to calculate the white quantity _Pw and the primary color component r _u contained in X, Y and Z. , the value of b _u ;

(5) If Z. The values are the minimum and Y. The value is the maximum value, then the unquantum state is in the p _w r _u g _u subspace. The white quantity _Pw and the primary color component contained in X, Y and Z should be calculated using the p _w r _u g _u type Liu's partition equation. The values of r _u , b _u ;

As long as the number of gray levels of p _w is not very small, the method described here is very accurate.

 4. Method of Quantizing Unknown Quantum State XYZ in Inverse Space - Liu's Quantization Inverse Equation

Purpose and use: The essence of Liu's quantized inverse equation is the description and induction of the quantum entanglement relationship in the inverse space, and the complement of the Liu's quantized positive equation to jointly deal with the microparticle world.

Principle: Light waves are associated with vision. The color temperature of the "light source" used to observe whether the background is "black" or "white" and observed is closely related to the observed results. The three stimuli of the state are [X _back .k, Yback-k, [Xback-w, Yback-w, Z _back . _w ], [X _w , Y _w , Z _w ], then you can find: Liu The positive quantization and the phase structure of the Liu's quantized inverse equation are exactly the opposite. The three sets of triple-excited values provide a stable support plane for the four-dimensional quantum space. Without one of them, the quantum space is also unstable.

The Liu's quantized inverse equation and the Liu's quantized positive equation given in sub-invention 2 are collectively referred to as Liu's quantum equation. From the perspective of quantum computing, both Liu's quantization equations have potential binary calculation functions. Because (1 red primary color photon + 1 green primary color photon = 1 yellow primary color photon), (1 green primary color photon + 1 blue primary color photon = 1 green primary color photon), (1 red primary color photon + 1) Blue-based photons = 1 magenta primary photon), it is based on this law that can evolve from the format of the Liu's primary color clamp equation to the format of Liu's quantization equation, which is not only in the equation format. Simplification, but a comprehensive consideration of the potential relationship between quantum computing and quantum superposition and actual physical state.

The format of Liu's quantized inverse equation:

Since cyan photons, magenta photons, and yellow photons are complementary entangled states, red photons, and blue photons, the complete Liu's quantization equation also includes the following format of Liu's inverse space quantization equation: )^^ Subspace: = ( ² + ² ) ■ ^0 = bg _u

Sin 0 = Y _b /R,cos Θ, cos 0 = YR

Z = [Z _tec ^(1-Rsin^)(1-Rcos^) + Z _i) sin ^ + Z _c cos ^]-p, +(1-p Z, in subspace: R = (V _r ² + Y _m ² f , tg Θ = rb _u

In the subspace: R = ( + V; f , tg Θ = gr _u

< Y = [Y _back _ _w (1 -Rsi (1 -Rcos ) + Y _g sin- ¹ Θ + Υ _γ cos- ¹ 0~]-p _w + (1-p. )Y _W

Z = [Y _back _ _w (1 - R sin - R cos + Z _g sin- ¹ Θ + Ζ _γ cos- ¹ 6>]-p _w +(1- p _w )Z _W Advantages of the method:

The Liu's quantization equation considers that two different background states and the illumination states used in the observation quantum space are sufficient and necessary conditions for the stability of the quantum space, thereby systematically summarizing white light with red, green, blue, yellow, The quantum entanglement between magenta and cyan in positive space and anti-space provides an effective technical way to construct multi-qubit quantum computing logic network, and also establishes Liu's p-rgb four-dimensional vector space and implements white Photonic communication technology, naked vision holographic television images and laid the foundation.

 5. Method for generating binocular complementary parallax images - Principle of visual physiology of binary algorithm logic

Purpose and principle: Utilizing binocular can not only observe the macroscopic world, but also interpret the microscopic quantum world by analyzing the binocular parallax function. The purpose of this sub-invention is to use the Liu's binocular parallax equation to integrate the three-dimensional macroscopic world into the human subconscious. Then, using Liu's quantum state coupling equation to realize the direct substitution of the primary color quantum state gray core, the purpose of copying the original image in the "parallel world" is achieved.

 1) Method for generating binocular complementary parallax images for Liu's quantization equation in positive space

Method, steps and uses:

In the first step, at the right end of the Liu's quantized positive equation, the quantum superposition state indicated by the plus sign is moved to the left end of the equation, and the white part after the plus sign is left in place, and the equation becomes the following format:

Pwfi^Ai space: R = (Y ² + Y ² ) ^1/2 , tg 0 = bjg _u

Sin 0 = Y _b /R,cos Θ, cos 0 = YR

-X _c ∞s ^^-p _w ) = p _w X _w

Y _c cos ^^-p _w ) = p _w Y _w

Z _c cos'0( -p _w ) = p _w Z _w

In the ΡΛ9„ subspace: R = (y _g ² + V; f , tg Θ = g _u /r _u

(1-p Zy _m (1-Rsin^)(1-Rcos^)-Z _g sin^1 -Z _y ∞s ^^-p _w ) = p _w Z _a Step 2, the basis of the format obtained above On, you can separate three kinds of single photons, such as red, green, and blue.

The equation evolves into the format shown below. This equation is called the Liu's binocular complementary parallax equation:

Λ Λ子空间: R = ( ² + ' tg iQu

Sin 0 = Y R, ∞s Θ, cos 0 = Y R

In the ftA subspace: R = (Y _r ² + Y _m ² , tge = r _u /b _u

Sin 9 = YR, cos 0 = Y _m /R

1-pJ[X- X _back — _k (1— R sin6>)(1 - R cos^) - X _r sin- ¹ 6»]} + [X _g cos ¹ Θ

1-pj[X- X _back _ _k (1-Rsin^)(1-Rcos^)-X _g sin- ¹ ^]} + [x„ cos ¹ θ{ -P,

1-Ρ„)[Υ- Y _back — _k (1 -Rsin6')(1 -Rcos^) - Y _g sin" ¹ θ] + [Υ„ cos- ¹ θ (1 - -PX

1 - )[Ζ - Y _back — _k (1-R sin^)(1 - R cosd) - Z _g sin- ¹ + [Z _b cos- ¹ ^(1 For convenience of description, the above equation is called Liu's binocular complementary parallax equation uses the subscript R to indicate that the three stimuli values in the brackets are the three stimuli of three individual photons, red, green, and blue.

 2) Use of Liu's binocular complementary parallax equation

(1) At the left end of the above three equations, the first subscript L function in the brackets indicates the color seen by the left eye, and the second subscript in the R brackets indicates the color seen by the right eye. , at the right end of the equations, is the three-excited value of standard white light p _u X _w , p _u Yw, PuZw, and PuXw, PuYw, PuZw are the white triplet values determined by _Pu , so the colors seen by the left and right eyes are actually complementary color pairs, according to the principle of visual physiology, within the range of resolvable field of view, If the binoculars see two complementary pixels in parallel, then binocular vision will be merged into a stereoscopic pixel by the brain. If the complementary pixels of the color seen by the left and right eyes are displayed on the raster 3D display, do not wear 3D. The visual aid can watch stereo TV, but the 3D display of the grating is not a good solution. If the Liu's quantum state coupling equation and the LC-SLM display of the invention are used to display the integrated color obtained by the brain, then the Liu's quantum state The coupled equation is able to convert the spatial phase Θ-modulated unknown quantum state XYZ into an unknown quantum state modulated by the intensity parameters “, g, b, which means that a naked-view holographic image can be generated. This is the best solution, this is The first use of Liu's binocular complementary parallax equation;

(2) If Liu's binocular complementary parallax equation is examined from the perspective of quantum computational logic, then Liu's binocular complementary parallax equation can be reflected from the perspective of visual physiology or from the perspective of easy interchangeability of different coding systems. For the Liu's binocular complementary parallax equations of different formats such as p _w g _u b _u , p _w r _u b _u , p _w r _u g _u , all that follows (1 red photon + 1 green photon = 1 yellow photon), (1 green photon + 1 blue light = 1 blue photon), (1 red photon + 1 blue sub = 1 magenta photon) and (1 red photon + 1 green) The quantum state superposition rule of photon +1 blue sub-n = 1 white photon) conforms to the binary and ternary interchangeability rules, which lays a solid foundation for the construction of multi-qubit quantum logic networks. This is the second use of Liu's binocular complementary parallax equation;

(3) In the second step of establishing the Liu's complementary parallax equation, the quantum states of the primary color photons are separated for different subspaces. The quantum states of different monochromatic photons are Θ and (1 _Pw ), which can be directly replaced by them. XYZ— r _v 'g _v 'b _v '→W _g d _b The parameters r _v ', g _v \ b _v ' in the gamma correction equation, thus deriving the Liu's quantum state coupling equation, which is Liu's binocular The third use of the complementary parallax equation.

 2) Method for generating binocular complementary parallax images for Liu's quantization equation in inverse space

Method and steps:

On the basis of understanding the positive spatial binocular complementary parallax equation, the method of establishing binocular complementary parallax images in the inverse space can be processed as follows. The binocular complementary parallax equations in the inverse space are listed below:

Α Α space: R = (V +V) ' tge = bjg _u

Sin 0 = Y R, ∞s Θ, cos 9 = Y R

P _w [X - (1 - si (1 - R cos ) - X _b sin- ¹ Θ _L +[p _w X _r cos-'e = (1- »)^

W ¹ - ^R s (1- Re — V sin- ]j + [p _w V s- ¹ 6»] _r

[Z - Z _back — _k (1— R si (1— R cos Z _t sin- + [p _w Z _r ∞s-'0] _R =(i- »)

In / subspace: R = (Y _r ² +Y _m ² † ,tg Θ = rb _u

_{P w [X - X back -} k (1-Rsin ^) (1-R cos) - X r sin- 1 Θ + LPA C0S = (1- j ^

Y- W ¹ - ^Rs ( ¹ - ^Rco )- ^sin — ]) + [Pj _g ^C0S —

_{[Z - Z tac ((-} ¾ (1 - Rsi (1- Rcos) - Z r sin- 1 COS = (1- pjz w

In the / v subspace: R = ( + Ttg g _u

P _w [X - X _back - _k (1-Rsin^)(1-R cos^) - X _g sin- ¹ Θ =(i- »)^

Si (1— Rcos )— y _g sin- ])

"Z- U- si (1- Rcos )- Z _g sinH + [p _w Z _b ∞s-'e] _R

6. Generate Liu's p _w - " _u g _u b _u 4D color space method and white quantity p _w multi-function

1) Principle and purpose: In essence, white light is the perfect light wave from the sun. The color light of each component of r, g, b is the residual component of white light that is attenuated and destroyed by the interaction of matter particles in the medium. , the so-called 3D image is not a perfect stereo image, away from white The light-constrained ", g, b three primary colors of light do not easily reach the gray balance requirement in the three-dimensional space, and the image also lacks the sense of depth. The purpose of the present invention is to define the behavior of the elementary particles using white parameters to create a p _w -r _u g _u b _u 4D color space, thereby achieving the purpose of reproducing a hologram light wave, exhibiting an overall color balance and a stereoscopic image conforming to visual psychology.

 2) Method:

Using the Liu's segmentation equation given in Sub-Invention 1, the white amount parameter p _w and the primary color quantities r _u , g _u , b _u can be calculated, and the three primary color quantities r _u , g _u , b _u can generate a 3D color space, but The absence of parameters representing depth space and parameters relating time and space, the present invention combines the white amount parameter p _w with the primary color quantities r _u , g _u , b _u to create a four-dimensional p _w -r _u g _u b _u Quantum space, where p _w is the time axis, r _u , g _u , b _u are the color space axes, and in the four-dimensional p _w -r _u g _u b _u quantum space, p _w is the command of the quantum world.

3) Multiple functions of white amount p _w :

(1) Explain the reason of "wave pack collapse" by using the white light quantity parameter p _w as the time coordinate;

(2) The white amount parameter _{Pu is} used as the vector parameter for controlling the visual depth of the image:

The 3D image is not exactly equivalent to the 4D stereo image. The 3D image is a three-dimensional color space formed by the three-dimensional vector of r _u , g _u , b _u , and the 4D stereo image uses the independent visual depth of the 3D image in the depth direction with an independent vector parameter. Quantize, control the position of the 3D image in the depth direction with the black background as the reference, and set the visual depth to be represented by D _u , then D _u is the visual psychological effect produced by the combination of the white amount Pw and the black amount (1 _Pw ). For relative visual depth, the present invention quantifies the relative visual depth using the following formula: D _u = (1-P _w )/P _w

(3) Using the transformation of the relative depth Du to make the stereoscopic image dynamic in the depth direction:

Observing the Liu's segmentation equation given in Invention 1, we can see that: XYZ color space is a composite color space described by three sets of ternary simultaneous equations, and the first simultaneous equation represents subspace p _u g _u b _u , the second simultaneous equation represents the subspace _Pu r _u b _u , and the third simultaneous equation represents the subspace p _w " _u g _u , subspace p _w g _u b _u , p _w " _u b _u , p _w " _u g _u isolates the hue of the visible light into three sections of uniform transition. Please note that because the ions have the "state coexistence" characteristic, they may exist in different spaces at the same time, so the present invention follows the light wave. The vibration frequency processes the quantum computation problem in sections, which is one of the effective methods for constructing quantum computational logic networks. It is also an effective method for constructing four-dimensional space-time coordinates, which makes the three primary color components r _u , g _u , b _u and white amount _Pu The linkage mechanism is formed, which changes with the change of the parameter P _w . When the p _w decreases from 1, the D _u gradually increases to the image, if there is a cat along the depth axis from X _back . _k Y _{back. k} Z _{back. k} crossing point color space Approaching the XwYwZw point, the vision will feel that the cat is walking along the depth axis. Conversely, the vision will think that the cat is moving toward the deep space. To get a more visible depth of vision, it should Increase the black and white contrast as much as possible to make the stereoscopic feeling of the image more satisfying the visual requirements;

(4) Using the white light amount parameter _{Pw to} transmit image information

Replacing the three primary color components r _u , g _u , b _{u of the} transmitted image with the white amount parameter _Pw can significantly save bandwidth, improve transmission speed and data transmission accuracy, and obtain an optimal stereoscopic reproduction effect. From the perspective of color space conversion, the four-dimensional _Pw- r _u g _u b _u Liu color space has the same color conversion accuracy effect as we have given a D yt property file connection space in the PCT/CN2011/001729 invention application. Both are much better than the traditional L'a'b' or L'uV uniform color space. The problem is that the D _|Xt y _t value must be obtained indirectly via the Pw-r _{u u u u u} space transmission, saving bandwidth and From the perspective of maintaining signal transmission accuracy, the four-dimensional Liu's _Pw- r _u g _u b _u color space is the most advantageous.

(5) Realize quantum communication using white light quantity parameter p _w

White light is synthesized by three-primary lasers, so the momentum of white light is much larger than that of a single-color laser. It is the best means to achieve quantum communication by transmitting a longer distance with the same amount of attenuation. Because the human eye can't bear strong laser excitation, the light source of the TV can be either laser or white light like LED. No matter what kind of white light is used, according to the quantum communication method we have given, red, green, and Blue, cyan, magenta, yellow, standard white, measured background black or background white, etc. 9 colors of three 剌 excitability [, Y _r , Z _r ], [X _g , Y _g ,

Zg], [Xb, Yb, Zb], [X. , Yc, Z _c ], [X _m , Ym, Z _m ], [Xy, Yy, Zy] , [X _w , Y _w , Z _w ], [Xback-k, Yback-k, Zback-k], [Xback-w, Yback-w, Z _tek . _w ] is defined as the standard data state shared by the sender and the receiver, in order to recover the "collapsed packet" of Copenhagen and to obtain a universal fit that can completely copy the unknown quantum state. Quantum cloning machine

(6) Realizing holographic display of stereoscopic image by using white light quantity parameter _Pw The quantum communication method provided by the present invention is a comprehensive method for communicating, recording and reproducing holograms by white light [p _w X _w , pwYw, p _w Z _w ] based on several Liu's clamp equations, which is coherent and simple. Practical, accurate, and low-cost, it is conducive to universal application.

(7) Using the attenuation behavior of the white light quantity parameter _Pw is convenient for correcting the quantum information variation caused by the decoherence to achieve the purpose of purifying the white light amount _Pw and the phase angle Θ color.

7. Method for transmitting unknown quantum state XYZ by using white light amount p _w and phase angle Θ

Purpose: To overcome the shortcomings of NTSC, PAL, SECAM three TV systems, and make full use of the advantages of quantum communication efficient and accurate. Method: Instead of transmitting the three primary color components XYZ, the present invention creates a method of transmitting the triple excitation value XYZ by transmitting the white light amount _Pw and the phase angle ,, that is, the receiving end uses the values of the parameters _Pw and Θ. Restores the triple 剌 value of the unknown quantum state XYX.

Step: In the first step, the three-excited value XYZ is calibrated with the three-intensity value of the white field to obtain a normalized three-shot value X. Y. Z. , that is, let Χ. = X / Xw, Υο Υ / Yw, Zo Z / Z ΐ

In the second step, the three-shot excitation value X of the object light wave is compared by using a large-selective small digital logic circuit. , Y. And Z. The size of the Liu's segmentation equation is selected according to the criteria given in Sub-invention 2;

In the third step, the white quantity _Pw and the primary color quantity g _u b _u or r _u b _u or r _u g _u are calculated by using the Liu's segmentation equation of the selected format to calculate the tangent value of the phase angle Θ of the object light wave according to the three pairs of primary color quantities, The tangent of the phase angle Θ is regarded as the quantum information parameter of the object light wave;

In the fourth step, A-D conversion is performed on the values of _Pw and Θ, and then transmitted to the receiving end;

In the fifth step, error correction is performed on the received binary sequence of _Pw and Θ: When the digitized sequence is transmitted in the channel, a bit error occurs when the information sequence is recovered at the receiving end due to noise interference and channel attenuation. Therefore, it is necessary to correct the binary code by the usual error correction coding technique;

In the sixth step, the preliminary corrected p _w and Θ values are subjected to D-A conversion, and then the "purification treatment" is performed on the white amount and the phase angle according to the method given in the sub-invention 8 to perform the "purification treatment" step. Inventions 8 - 1 and 8 - 2);

In the seventh step, the _Pw and Θ values after the "purification treatment" are substituted into the Liu's quantization equation given in the sub-invention 2), and the data of the unknown quantum state XYZ from the transmitting end can be restored.

 8. Liu's sound and light interpretation and verification method explaining the cause of "wave packet collapse"

 1) Historical background: Wave-particle duality is the core and pillar of quantum science, but in the development of quantum science, the Copenhagen interpretation of "wave pack collapse" has caused a lot of controversy, this is a wave and two The closely related phenomenon is closely related to the basic theory of quantum theory and the major problems in practical application. Copenhagen Interpretation believes: When conducting the "observation" of photon position and momentum, the light waves that permeate the large range of space will "shrink" into "Needle wave", so the position of the photon is found to be the position after the light wave shrinks. Which part of the original light wave will shrink and remain? It is impossible to know beforehand that the wave contraction follows the law of probability. Except for the contracted part of the original wave, the rest disappears. Since the microscopic particles have the characteristics of "multiple states coexisting", it is uncertain what the observer actually observes. The commonly used observation devices are always large enough to be macroscopic objects that cannot be compared to the particle size (eg CCD photosensors), according to Copenhagen Interpretation: "Electronic waves contract when they interact with macroscopic objects," but "Why does the wave shrink?" " "Where did the waves have disappeared before the contraction and disappeared after the contraction?", the direct quantum theory has not given a clear explanation; Einstein is a quantum One of the founders, but he has always disagreed with Copenhagen's probabilistic interpretation of the "wave pack collapse" issue. He ridiculed that "God does not play dice games", and later, he also supports German physicists who support Copenhagen interpretation. Bonn had several confrontations at the academic conference. Einstein's thinking about quantum theory is more than thinking about relativity. Even so, he himself regrets to say: "The conscious thinking of 50 years has not brought me closer to the question of 'what is the quantum of light'? s answer". The actual situation is: Although quantum theory can only make probabilistic predictions for the behavior of a particle, it can make accurate predictions for a large number of electronic collections. If you throw a dice 10,000 times, you can correctly predict the proportion of even points. About 50%, the probability of 1 point is 1 / 6, in this case, the quantum researcher accepted the "probability interpretation" and used the probabilistic method as a tool to solve practical problems, thus extending The well-known "uncertainty relationship" and "quantum state non-cloning theorem" in physics, until now, "uncertainty relationship" and "quantum state non-cloning theorem" are insurmountable red lines defined by quantum science. Subsequent researchers have become accustomed to the "uncertainty relationship" and "quantum state non-cloning theorem" as the rules that must be followed.

 2) The interpretation of the truth about "wave pack collapse" and the verification of Liu's sound and light interpretation

According to the research of the present invention, Einstein’s questioning of "Copenhagen wave pack interpretation" is indeed justified, just facing When the debater is aggressive, he lacks sufficient evidence at hand.

Regarding the wave pack collapse problem, the present invention proposes the following interpretation different from Copenhagen: According to the Copenhagen interpretation, when measuring the incident light wave, only the particle packing of the light wave can be measured due to the "wave packet collapse". Information, photon fluctuation information inexplicably "suddenly disappeared", this is not true. In order to explain the reason for the incorrectness, it is necessary to analyze the behavior of the photon after reaching the sensor: After reaching the sensor, the light contacts the substance particles to form a reflection component and a scattering component, in the scattered rays, except for the original wavelength λ. In addition to the composition, there is also a component with a wavelength greater than λ. This phenomenon is called the Compton effect. The Compton effect increases the average wavelength of the incident light wave. The shorter the wavelength, the faster the attenuation. The so-called "red shift" occurs, so the wavelength distribution of the three primary colors is unbalanced, which causes the fluctuating phase to be twisted and deformed. If in the order of decreasing energy and at some quantum interval, the "collapse" is measured by the light spot or the light reflection from the maximum spot to the spot without the spot, that is, the i group of three spots of the i spot are continuously measured. Excitation value, using the i-group triple-excitation value, i amplitude value and i-wavelength value can be calculated. According to these amplitude and wavelength values, a wave surface reflecting the Cape line effect can be drawn, if the wave surface is According to the comparison of the wave surfaces drawn by Copenhagen Interpretation, it can be found that they are two wave surfaces with orthogonal and complementary characteristics. When the transverse wave waveform shrinks into a spot, the longitudinal wave waveform is stretched out and becomes the Cape line effect. The waveform that is represented. To further understand this new interpretation, imagine that in a stormy summer night, a flash of lightning suddenly appears in front of you, and then immediately or a little later, the thunder will follow, and if the lightning flashes strongly above the head, then The thunder will sound as the lightning will soon sound and the tone will go from high to low. If the lightning flashes from a farther place, then the thunder will sound later and the tone will run from low to high; visible, lightning and Thunder is two aspects of the same thing, and they have complementary characteristics. During observation, the particle's particle behavior appears as a macroscopic spot on the screen. This is like the lightning seen by the vision. The volatility of the photon is expressed as a thunder that follows the Cape effect. That is, only visible on the screen. The particle nature of the light spot, the thunder is not shown on the screen. This is because the light wave is a transverse wave, and the thunder is a longitudinal wave. If the waveform of the longitudinal wave component is recorded and further played out by the speaker, it can be observed on the screen. To the particle nature of photons, the volatility of photons is heard by hearing. If the two are considered together, then all the "wave-particle duality" information of the observed photons can be calculated, so that the original thought "Uncertainty relationship" becomes "deterministic relationship", inaccurate "probability interpretation" becomes accurate algebraic operation result, and "quantum state non-cloning theorem" becomes "natural world allows people to strictly copy an unknown quantum state The Liu's Cloning Theorem", which lays a solid foundation for the construction of multi-qubit quantum computing logic networks, for the convenience of narrative Interpretation and probability difference between Copenhagen interpretation, the present invention is simply referred to as the new interpretation Liu acoustooptic interpretation.

In order to verify the correctness of Liu's acousto-optic interpretation, the present invention measures the three-excited value of the red photon spot X "Y"Z", the three-shot excitation value of the green photon spot XgY _g Zg, and the three-shot excitation value of the blue sub-spot. X _b Y _b Z _b and the three-shot excitation value X _W Y _W Z _{W of the} white photon spot, and then clamp calculations respectively, which proves the correctness of Liu's acousto-optic interpretation, before making a more detailed verification statement ( Referring to the sub-invention 8), the red primary color is first described as an example.

Assume that the three-shot excitation value of the measured red photon spot is X "Y". A series of triple-excited values are measured in order of light intensity from weak to strong, and then use our publication number as Pub.No.: WO/2012 /116468 The Liu's primary color clamp equation given in the invention, the clamp calculation of the series of ordered triple-excited values, can accurately calculate a series of unknown quantum states XYZ as follows, including the clamp Position brightness

Ay, - y _h . Y - Y

 ' t 'back

a, where Y _Rt represents the clamp brightness of the red light wave, represents the lightning intensity visually perceived at time t, and λ represents the wavelength of the instantaneous light wave. The present invention refers to the function λ as the Liu's wave model, and the triple 剌 excitation value [λΧ , λ1⁄4, λΖ] represents the intensity of the auditory stimulus of the quantum state at time t, if a represents The unknown quantum state [Χ, Υ, Ζ] shows the spot size on the screen, then 3⁄4 accurately predicts the virtual image of the unknown quantum state [X, Y _t , Z] not displayed on the screen, the clamp processing reaches The effect is: the light wave of the three 剌 值为 [Χ, Υ, Ζ] and the light of the three 剌 值为 [λΧ, λ1⁄4, λΖ] are the same, which means [Χ, Υ, Ζ] and [λΧ , λ1⁄4, λΖ] describes the same particle, according to Liu's sound and light interpretation, a is the particle information of the photon, because the measurement leads to the "wave packet collapse", which shows the clamp base color amount 3⁄4, parameter 3⁄4 It is the volatility information of the photon. From the above Liu's wave model, it can be seen that λ is a function of the variable Y _t , and the brightness distribution of Y _t in time Δ 1 is the part of the wave packet lost by the Copenhagen interpretation. According to the Liu's wave model given by the Liu's primary color clamp equation, the part of the wave packet that is mistaken for the loss is also a deterministic, closable quantum information, that is, the primary color quantities a and 3⁄4 have a deterministic relationship: Unknown quantum state The ionic information of XYZ is a, the volatility information is λ, and the value of λ depends on the parameter Y _t , so Y _t is the parameter that directly expresses the volatility, but the transverse wave waveform has gradually changed into the longitudinal wave waveform, the red light particle Wave-particle duality is not an "uncertainty relationship". If you further perform a "gamma correction" on Y _t to map it to the white quantity p _w , then p _w is still determined. Please further compare the parameters Y _Rt , λ, a _t , a and _Pw given by the Liu's basic color equation with the De Broglie wave model shown below. The De Broglie wave model is: λ = -, where = 6.626 χ 10— ³⁴ J - s

 P

After comparison, it can be known that in the material wave model of De Broglie as shown above, the parameter h is a Planck constant, the momentum p is a variable, and the deductive conclusion is that there is an uncertainty relationship; In, the corresponding to h is the observed state X _W Y _W Z _W and the background state

_{X back. K Y ba ek.} K Z baek. K ( anti space _{X baek. W Y baek .wZ baek} . W) determined constant values, and momentum p de Broglie wave model corresponds wave Liu The Y _Rt in the model is from the observed state X _W Y _W Z _W and the background state X _back . _k Y _back . _k Z _back . _k (in the inverse space is X _back . _w Y _back .wZ _back . _w ) and the clamp The value determined by the brightness Y _Rt , Y _Rt is a value determined by the observation state XwY _w Z _w , the background state X _back . _k Y _back . _k Z _back . _k and the unknown quantum state XYZ, and both the wavelength and the stimuli are determined. The white light quantity Pw and X _W Y _W Z _W , Xback-kYback-kZback-k and the unknown quantum state XYZ have entanglement characteristics, so the white light quantity Pw and the momentum p in the material wave model of De Broglie correspond to each other. However, momentum p does not include the environment in which it interacts (other systems), is an environmentally isolated system, and the Liu's primary color clamp equation involves background state data, which is shared by any quantum subsystem. The interaction environment, so in essence, the De Broglie wave model is still deducted as " Deterministic relations" and "quantum non-cloning theorem", only because the Planck constant is a small value, in the case where the particle is divided sufficiently small, or only when the primary color amount a is sufficiently small, The Planckian constant is obtained, and the parameters derived from the Liu's primary color clamp equation are completely determined and the "quantum state cloning theorem". Strictly speaking, the De Broglie wave model is conditionally established, Liu Shibo The model is the exact model that is universally applicable.

9. Method for purifying white light amount p _w and phase angle 一 - Liu's white and phase angle correction equation

Principle: In the sub-invention 6, the receiving end measures the white light, and recalls the interpretation of Liu's sound and light given by the "wave pack collapse" in the present invention. In order to restore the seemingly collapsed wave packet, it is necessary to restore the true color. The longitudinal wave having the Cape line effect is calculated, and the "bell-shaped wave" of the transverse wave before observation is perfectly restored according to the longitudinal wave waveform, but with the attenuation of the amount of white light, the three primary color components having shorter wavelengths are attenuated faster. White light appears red, so the observation of white light also causes the three primary color components to lose balance and phase torsion, which is no longer pure white light, which leads to the degradation of the quality of the quantum entangled state, and the so-called "decoherence" phenomenon occurs. The propagation distance increases and the quality of the entangled state becomes worse and worse. Therefore, it is necessary to purify the object light wave by purifying the white light amount p _w and the phase angle ,, so that the wave-particle duality parameters of the unknown quantum state XYZ can be maintained. .

Method:

 1) Method for purifying the amount of white light Pw at the receiving end - Liu's white clamp equation:

Method steps:

The correction of the white light amount Pw should be performed before the correction of the phase angle ,. First, the received white light amount _Pw is clamp-corrected to create conditions for further correcting the phase angle 。.

The first step is to measure the amount of white light received, assuming that the measured three-shot excitation value is XYZ;

In the second step, the white amount is purified by using the Liu's white clamp equation shown below, in order to allow each white amount to be purified and the unit white amount [X _w , Y _w , z _w ] Have the same chromaticity coordinates: X = ^ -p _w )X _back _ _{k + Pw} X _w

^y _t = { p _w )y _back _ _k + p _w y _w

{ Z = ^ -p _w )Z _back _ _k +p _w Z _w

The equation has a total of three variable parameters, λ, Y _t and p _ws , in the array [X _ba . _k .k, Yback-k, Z _ba . _k .k] and [X _w , Y _w , Z _w ] respectively represent the triple 剌 value of the black background and the triple 剌 value of the standard white point, which are the data states stored in the system, and the variable parameter λ represents the measured white light. The wavelength, called the color appearance retention coefficient, maintains the chromaticity coordinate of the triple 剌 XY _t Z by the parameter λ is always equal to the chromaticity coordinate of the standard white point, is the white quantity parameter to be obtained, and the data is unknown;

The third step is to solve the Liu's white clamp equation, and the model for calculating the clamp luminance value of white XY _t Z can be obtained. The parameters at the right end of the equal sign are all

Step, calculate λ

 Υ, -Υ

 t b, ack-k

The fifth step is to calculate the amount of volatility white p

 Back-k

In the sixth step, by calculating the Liu's white clamp equation, the model for calculating the white amount p _w as shown below can be obtained: Calculating the particle white quantity p _w back-k Substituting the value of the clamp brightness value 丫 into the above formula, The value of Pw, which is the final correction value of the white amount.

The correctness of Liu's acousto-optic interpretation is proved by the derived parameter model of the white clamp equation: Observing the wave function λ derived from the Liu's white clamp equation, the wavelength is a function of the white lightness Y _t , because Y _t is the clamp brightness. So it is a parameter that provides sound waves for the ear. Looking at the white quantity function p _w , p _w is also a function of the clamp brightness Y _t , but it is not related to λ, which means: the white quantity p _{w is} only white light The intensity is related to the description of the white light particle. The volatility and particle property of the white light particle can be represented by the dual _Pw ' and p respectively. It has a certain relationship. It can be seen that: Liu's sound and light interpretation negates the interpretation of Copenhagen. And the negation of the "uncertainty relationship" is based on experimental data and has sufficient basis.

 2) Method of correcting the red, green and blue components of white light at the receiving end - Liu's three primary color phase angle clamp equation:

OBJECTIVE: Correction of the three primary color components of red, green and blue refers to the correction of the phase Θ in different sub-gamuts. Because the three primary colors have different wavelengths, the attenuation speeds are not uniform, so the correction of the phase angle also needs to be 3 The gamut is performed separately.

Method:

In the first step, the three excitation values of red photon, green photon, and blue light are [x _R , y _R , z _R ], [x _G , y _G , z _G ] , [X _B , Y _B , Z _B ] , according to the Liu's complementary entangled state equation given in the second invention, the three-shot excitation values of the three primary color photons are as follows: X _R =p _w X _r ∞se X _G = p _w X _g cos- ¹ Θ X _B =p _w X _b ∞s^

Y _R =p _w Y _r cos-θ Y _G =p _w Y _g cos^ Y _B = p _w Y _b cos- ¹ Θ

Z _R =p _w Z _r cos' Θ Z _B = p _w Z _b cos' 代 By substituting the white amount correction value _Pw calculated in 2) and the received phase angle value into the above equation, the primary color triple stimuli value can be obtained. [x _R , y _R , z _R ], [K, Z _G ], [HZ _b ] is calculated; the second step, because the received phase angle value Θ is attenuated during transmission, and different sub-gamut The decay speeds are not equal, so you need to correct the flaws. The method is: enter the three 剌 excital values [x _R , y _R , z _R ], [x _G , y _G , z _G ], [x _B , y _B , z _B ] into the following Liu Phase angle clamp equation:

-^) ^X back-k +^r

The Liu's phase angle clamp equation in the p _w g _u b _u subspace is: into YR ¹

-e)z _back - _k +ez _r

The Liu's phase angle clamp equation in the Pw "ub _u subspace is:

ζ ζ _ΰ = (ι-θ): + ΘΖ„

The Liu's phase angle clamp equation in p _w " _u g _u subspace is: γ _γι = ( ¹

- ⁶ ) ^Z back-k ^+6Z b The third step is to solve the Liu's phase angle clamp equation, and obtain the phase angle correction value θ of the red primary light, the green primary light, and the blue primary light, respectively, and the phase angle of each band. The calculation of the correction value is as follows:

(1) Correction of the phase angle of the red photon: Solving the Liu's phase angle clamp equation in the p _w g _u b _u subspace, you can get:

a) Clamp brightness of red photon: Rt

+ Yback k {^r ~ ^back-k )― ^back-k ( ^— ^ back-k b) The Liu's wave function of the red photon: Λ

(Z _r ― Z _back — _k ) _ Z _R ( _R ― X _back _ _k )

In order to avoid confusion with the De Broglie wave function, the present invention refers to the above function as a Liu's wave function;

C) Calculate the clamp phase angle of the red photon: θ' 'Rt

Υ -Υ back-k d) Phase angle after red photon is purified: e- H -k

(2) Medium wave band phase angle correction model: Solving the Liu's phase angle clamp equation in the _Pw r _u b _u subspace, you can get:

a) Clamp brightness of green photon: Ί ( Gt

 + one back-k y back-k \ g back-k

b) Liu's wave function of green photon:

^Gt ^back-k ^back-k _t

In order to avoid confusion with the De Broglie wave function, the present invention refers to the above function as a Liu's wave function;

C) Clamp phase angle of green photon: θ'

' g ' back-k d) The phase angle after the green photon is purified is: Θ = ^Υ :

 ^back-k

(3) The short-wavelength phase angle correction mode solves the Liu's phase angle clamp equation in the _Pw r _u g _u subspace, and obtains:

Clamp brightness of blue light:

 + 'b '-back-k

V

b) Liu's wave function of the blue light: y

 -back-k '-B

 Y _ y

c) the phase angle of the blue light:

d) The phase angle after the blue light is purified: θ = ^k Because in the calculation program of Liu's quantization equation, r, g, b are all normalized values, so the purified phase angle is not needed in the program flow. The red, green, and blue light sub-labels are marked with subscripts, and should be uniformly represented by Θ.

The correctness of Liu's acousto-optic interpretation is proved by the derived model of Liu's three-primary phase angle clamp equation: Observing the wave function λ derived from Liu's phase angle clamp equation, the wavelengths are white quantities Y _Rt , Y _Gt , The function of Y _Bt , because Y _t is the clamp brightness, it is also a parameter that provides sound waves for hearing. Looking at the purified phase angle 6, although they are also functions of Y _Rt , Y _Gt , Y _Bt , they are It is not related to λ, which means: The phase angle after purification is related to the magnitude of the clamp brightness. It is a description of the phase angle particle property. The volatility and particle property of the primary color light can be separated by the θ' and Θ respectively. Representation, with a certain relationship, which further proves: Liu’s interpretation of sound and light The negation of Copenhagen's interpretation and the denial of "uncertainty relationship" are based on experimental data and are fully based.

 10. Method of restoring the tristimulus value XYZ at the receiving end

Purpose: The light source XYZ output at the transmitting end is transmitted to the receiving end without being intact. The original face of XYZ is hidden, and it is disguised as white quantity Pu and phase angle Θ for transmission. The obtained _Pp and Θ can achieve the purpose of restoring the unknown quantum state XYZ.

Method: If the object involved is in the positive material space, then the white amount _Pu and the phase angle after purification are substituted into the invention 1

-4) Given the Liu's quantized positive equation, the data of the unknown quantum state XYZ can be restored. If the object involved is in the antimatter space, then the purified white quantity _Pu and the phase angle are substituted into the sub-subject. The Liu's quantized inverse equation given in Invention 3 can be restored to the unknown quantum state XYZ.

The advantages of this method: efficient and precise.

1 1 . A method of mapping the corrected white amount p _u to the white amount at the receiving end

Purpose: As mentioned above, NTSC, PAL, SECAM three TV systems are analog processing and transmission systems for analog TV signals. To save transmission bandwidth, the three primary color analog TV signals first form a luminance signal and two color difference signals, and then Making the color difference signal modulate, mix and turn into a full TV signal for transmission, which is a complicated and damage fidelity method. From analog TV to digital TV, it is the application of digital technology. What really caught a lot of interest was the publication of a groundbreaking paper by the six scientists in four countries, IBM Bennet, in 1993, in the "Physical Review Letters": "Transmitting Unknown Quantum States via Classical and EPR Channels" The paper proposes a method for transmitting an unknown quantum state of a particle to another particle in the distance, so that the particle is in the unknown quantum state, and the original particle is not transmitted. This is called "" Quantum teleportation ".,

The method of restoring the light oscillating value XYZ of the object at the receiving end by using the second entangled state equation of Liu is given above. The problem now is: To realize the so-called "quantum teleportation", then it must be The unknown quantum state of one particle is transmitted to another particle in the distance, that is, the white quantity p _u in the unknown quantum state needs to be transmitted to another particle located in the display color space, so that the white bit in the quantum bit of the particle amount p _u ^ associated with a function occur through, since the p _u ^ classical information portion belonging superposition direct product of a different color gamut, it can use classical mathematical methods can be established as a function of both p _v = F( _Pu ), and then let the associated function be on the unknown quantum state of the object light wave, and the original particle is not transmitted, which really realizes the so-called "quantum teleportation", from which it seems The white quantity p _{u of the} shooting space is mapped to the white quantity of the display color space. It is an effective way to realize the "quantum teleportation". The specific steps of establishing the function relationship p _v = F( _Pu ) are described below.

Method:

The goal of this method is very simple, is to establish a functional relationship p _v = F ( _Pu ), and then use the function p _v = F (p ^ 乍 as a bridge to convert the spatial phase modulation of XYZ to ", g in the display color space" , b light emphasizes the purpose of the system.

In the first step, in order to calibrate the working state of the camera, a standard 21-level white point-adapted gray scale can be taken, and a triple-magnitude array [Ri, Gi, Βι] is obtained, and then the sub-invention 1 is mentioned. The standard matrix transformation equation converts [Ri, Gi, Bi] into a standard triple-excited array [Xi, Yi, Zi] _; using the triple-excited array [X _ui , Yui, Z _ui ] as the original data, and then Our international application number is

The Liu white balance clamp equation given in sub-invention 5 of the PCT/CN2012/073178 invention application calculates an array of reference white quantities [p _ui ] _{; the} second step, in order to calibrate the operating state of the display, can be on the display Display a standard 21-level gray scale with white point adaptation, measure the three-magnitude array [X _vi , Yvi, Z _vi ] of the gray scale, and then calculate the display with the same Liu's white balance clamp equation White volume array [p _vi ] _;

In the third step, the white quantity array [p _vi ] is used as the dependent variable array, and the camera's white quantity array [p _ui ] is used as the independent variable array to fit the data, and the power function p _v = p TM can be obtained.

This power function is also the pipeline function that was involved in our invention application published under Pub. No.: WO/2012/116468.

12. Method for displaying 4D holographic image by means of Liu's quantum state coupling equation and normally black TFT LCD display

Purpose: The present invention and the aforementioned quantum communication technology, quantum computer technology given in sub-invention 13 and normally white TFT given in sub-invention 12. LCD liquid crystal displays display 4D holographic images on a computer display together to form a complete, fast and accurate naked-view, holographic 4D television system.

From the perspective of holographic technology, the task of the Liu's quantum state coupled equation is to map the quantum state of the primary color to the 'grey kernel' parameter, and to convert the spatial phase modulation represented by [λΧ, λΧ, λΧ] into " The spatial intensity modulation represented by gb.

 1) Evolution from the Liu's gamma correction equation to the Liu's quantum state coupled equation:

The "XYZ based on the new principle" is shown below in the sub-invention 2 of the invention application of the publication No.: Pub. No.: WO/2012/116468 and International Application No. PCT/CN2011/000327. r _v 'g _v 'b _v '- (Wgdb gamma correction equation):

In Λ Λ子空间

λ = ΐ-Γ;)(ΐ-9)(ΐ-)) , +Γ;(ΐ-9)(ΐ-)) _Γ + (ΐ-Γ;)9(ΐ-)) _£ ,

+^-^-9)bY _b +{^-^gbY _c +r;^-g^bY _m +r _v ^, g^-bjY _y +r _v ^, gbY _w λλΖΖ == (1 _ r _v ' ) (1 _ gf ) (1 _ Jb) + r _v (1 _ gf ) (1 _ Jb)Z _r + (1 _ r _v ' ) gf (1 _ _g

+(1 ) )((^1-_gfi^)bZZ _bb ++ ( (l1-r; ) )ggfbJbZZ _cc ++rr _v ' (1-_ggf))bJbZZ _mm ++r _v 'g (1 _Jb) Z _y +r _v 'gbZ,

In the PA subspace

XY = -r)^-g _v ^,] j^-b)Y _k +r^-g; ^] j^-b)Y _r +^-r)g; ^- )Υ _ς

XZ=^-r^-g _v ' ^] j^-b ⁾ jZ _k +ri^-g _v ' ^] j^-b ⁾ jZ _r +i^-r ⁾ jg _v ' ^-bb, Z _g

+fl-r)(lg;))Z _b ++( (l1--rr)")gg; _v 'b)ZZ _cc ++rr(^l--gg; _v ') ⁾ jb)ZZ _mm + +rrgg;:(l-))Z _y +rg _v 'bZ _w

In the subspace

XX=^-r^-g^-b ^X _k +r^-g^-b ^] jX _r +^-r ⁾ jg^-b ^] jX _g +^-r^-g^b X _b +^ -r^gb X _c +r^-g^b _v 'X _m +rgi^-b _v ' ^] jXy+rgb _v 'X _] W

λΥ = (ΐ-Γ)(ΐ- _& )ίΐ-);)γ,+Γίΐ- _& )ίΐ-);)Υ _Γ +ίΐ- ΐ -);)Υ _£ ,

+(1-rJ 1 -g)b _v ' _b + (lr)g);y _c + r (1 -g)b _v 'Y _m + rg (1 _ Jb _v ' jY _y + rgb _v 'Y _w

λΖ = (1 _gf)(1 _Jb +r (1 _gf)(1 _Jb )Z _r +(1 _r)gf (1 _ )Zg

+ -r ^] 1 -g)b _v 'Z _b + -r)gb _v 'Z _c + r (1 -g)b _v 'Z _m + rg (1 _ Jb )z _y + rgb _v 'Z _w

= ( _Pv ), y

Where: b _v '

 (1) Purpose and principle:

In order to faithfully display the original image from the photographing end on the display end, the quantum state of the primary color from the photographing end must be copied to the primary color quantum state of the display space. The present invention uses the gray kernel parameters rg _v ', b _v ' as the primary color of the display end. The interface parameter forms a mapping relationship with the primary color photons r _u , g _u , b _{u of the} shooting color space, and rg _v ', b _v ' and r _u , g _u , b _u have opposite rotation directions, and the quantum states are θ. That is to say: Unknown quantum states can coexist in parallel space in the same state through four-dimensional space-time. This method can not only achieve the goal of faithfully copying the original image, but also significantly improve the efficiency of the algorithm.

The evolution of the Liu's gamma correction equation into the Liu's quantum state coupling equation can significantly simplify the complexity of the receiving end equipment, improve the algorithm efficiency of the receiving end and greatly reduce the time consumption.

 (2) Evolution method:

According to the Liu's binocular parallax equation given in the third invention, the right eye sees the triple-excitation value of the reverse-rotating red, green, and blue particles, and its coupler in the Liu's gamma correction equation is the gray kernel. The middle, forward-rotating red photon "gb, because the data states of the shooting space and the display space are equal, that is, have the same triple stimuli [, Yr, Z _r ], [X _g , Y _g , 3⁄4] , [X _b , Y _b , Z _b ], [Xc, Yc, Z

[Xm, Y _m , Z _m ], [X _y , Y _y , Z _y ], so the phase angle Θ of the shooting space and the display space are equivalent, according to the Liu's binocular parallax equation given in the sub-invention 3 And the Liu's pipe function given by the invention 9 can obtain the rgb _v 'quantization function formula as follows: r; = X _r cos ¹ θ(1 - ρ _ν ) = Χ _Γ cos ¹ θ(ΐ - p - ), g _v ' = Y _r cos ¹ θ(1 -ρ _ν ) = Υ _Γ cos ¹ θ(ΐ - p - ) b: = Z _r cos 6(1 -p _v ) = Z _r cos' ¹ θ( ΐ - /» ) According to this, the parameters r _v ', g _v ', b _v ' in the XYZ-r _v 'g _v 'b _v '→W _g d _b gamma correction equation can be replaced by the quantization function , that is, a function of the phase angle Θ and the white amount _Pu , which has great advantages: First, the efficiency of the algorithm can be significantly improved, and second, the seamless connection with the quantized shooting space can be utilized, and the binary can be fully utilized. The quantum computer method combined with the ternary is used for quantum operations. In the ternary notation, it is convenient to represent 1/3. Unlike in decimal, it needs to be represented by infinite decimals, but from the decimal to Binary and decimal conversions are very convenient This artificial intelligence to solve the problem, it is a very good property. The modified XYZ—“ _v 'g _v 'b _v '→Wgd _b gamma correction equation is listed below:

 In the PvfifA subspace

+ [(1-r)(1-ft)Z _g+ (1-r)ftZ _{c +} r(1-ft)Z _y+ rftZ„][Z _f cos- ¹ ^(lp in P/ _V fif _v subspace

It is worth noting that: According to the unknown quantum state XYZ value at the left end of the equation, the chromaticity coordinate values x _t , y _t , z _t can be conveniently calculated.

 X Y

y _t z _t = ix _t -y _t

X+Y+Z ¹ X+Y+Z

In our application for PCT/CN2011/001729, we have given a connection space for the D yt profile, in which the parameters x _t and yt are obtained in this way.

The present invention refers to a new equation evolved from the XYZ-r _v 'g _v 'b _v '→W _g d _b gamma correction equation as the Liu's quantum state coupled equation.

2) Multiple uses of the Liu's quantum state coupled equation:

 (1) Liu's binocular parallax equation integrates the three-dimensional material world into the subconscious of the brain. Liu's quantum state coupling equation further places the wonderful microscopic material world in the four-dimensional space and time determined by time and space. Humans can observe and experience the wonderful universe with quantum-level temporal precision or resolution through visual and auditory perception, which is more important for images for component analysis, long-range radar, medical analysis, because it is placed in four-dimensional holography. The fidelity of the image is consistent with the visual psychology to a better extent than the image displayed by any other method, and the cost is the lowest.

It can be seen from the coupling equation of Liu's quantum state that [λΧ, λΥ, λΖ] at the left end of the equation can be equivalently replaced as follows:

=p _w Z

According to the above alternative relationship, it can be clearly seen that the parameters [λΧ, λΥ, λΖ] are descriptions of the wave-particle duality of the unknown quantum state; the parameters [PwYw(xt/y _t ), PwYw, p _w Y _w (1- x _t -y _t )] is a description of the amplitude and phase holographic information; the parameters [p _w X, p _w Y, p _w Z] are descriptions of the acousto-optic modulation characteristics of the microscopic particles, and also describe the parameters p _w , parameters λ and gray kernel parameters are equivalent between the three;

(2) The left end of the equation records the amplitude and phase information of the wavefront of the object light wave. The spatial phase modulation of the wavefront is converted to the right-end ", g, b spatial intensity modulation by the Liu's quantum state coupling equation, and the nakedness is satisfactorily realized. Depending on the display of the 4D holographic image; (3) The original primary color amount parameter "gb _v ' at the right end of the equation means gray kernel or nucleus, which respectively form a mapping relationship with the three primary colors r _u , g _u , b _u at the shooting end, because the photon or electron itself is an electromagnetic wave, so "gb _v ' and " _u , g _u , b _u form a nuclear magnetic map or an acousto-optic coupling relationship;

(4) The Liu's quantum state coupling equation is derived from the XYZ—“ _v 'g _v 'b _v '→Wgd _b gamma correction equation. It inherits the gamma correction function and can eliminate the inverse square law's intensity on the light wave. influences;

 (5) Based on the closable conclusion of the quantum state given by Liu's acousto-optic interpretation, the Liu's quantum state coupled equation can perfectly map the quantum states of the three primary color photons to the right end of the equation.

 13. Method for displaying 4D holographic image on a normally white TFT LCD liquid crystal display using Liu's quantum state coupling equation

Purpose: Mobile communication devices such as computers and mobile phones operate in a normally white display state. With the rapid increase of cross-media images, it is often necessary to quickly switch between the two display states.

Method:

From the following inverse equation of the Liu's quantum state coupled equation, we can see the commonality and difference between it and the Liu's quantum state coupled equation: in the subspace

X = [^-g)^-b)X _{k +} g^-b)X _{g +} ^-g)bX _{b +} gbX _c ][x _r cos- ¹ e^- _P -)]

In the P scorpion space

In the P A subspace

+ [(1-r)(1-g)Z _t+ (1-■r)gZ _c + r(1-g)Z _m +rgZ„]-[l-cos- ¹ ^(1-p _v positive equation The only difference from the inverse equation is that the parameters (1 p _v ) and ^ are swapped.

14. Method of Realizing Quantum Computer in Technology - Liu's Method of Constructing Multi-qubit Computing Logic 1. Purpose:

Quantum communication, quantum computer and photonic computer technology are involved in the processing of multiple qubits. How to develop quantum logic networks with multiple qubits is a concern of the international academic community. Nobel laureate Feynman has raised the question: Can classical computers accurately simulate the evolution of quantum systems? Quantum mechanics believes that it is impossible. The reason is: The evolution of isolated quantum systems is a positive transformation. The non-cloning theorem of quantum states shows that this contradicts the uncertainty principle of quantum mechanics. This view is incorrect. According to Liu's sound and light interpretation, the relationship between the position and momentum of microscopic particles is determined. An unknown quantum state can be faithfully cloned. This is the technical realization of quantum computers. The convenience of the door, coupled with the multi-qubit computing logic established by the present invention, mass production of inexpensive quantum computers and the subsequent manufacture of photonic computers becomes a matter of course.

 2) Principles and methods for implementing multi-qubit computing logic:

There have been long-standing debates about Schrödinger's cat state. The experimental method designed by Schrödinger has caused controversy over dead cats, live cats, and undead cats. In fact, the birth and death of cats are only two transient states in a cat's life. Just like the opening and closing of the circuit, it is a fast completion of the binary behavior. Since the cat is not a dead cat from birth, middle age to aging, then the mouse game should be "cat". The main theme, it is reasonable to describe the behavior of the cat in hexadecimal.

The cat's "life calendar" can be regarded as a visually visible spectrum, and the whole spectrum is divided into three sub-gamuts such as p _w g _u b _u , _Pw " _u bu , _Pw " _u g _u , then the cat in the field of view Become a dynamic holographic stereo image that can walk freely in the positive and negative spaces; assume that the "cat" timing method is 27 hours a day, and the 9-hour work system is implemented, which divides the day into _Pu g _u b _u , p _u "ubu and _Pu " _u g _u and other 3 time periods, 13.5 hours during the day and 13.5 hours for the night, then, "the timing method of the cat" and 24 hours a day for humans, 8 hours a day, 12 hours a day, There is no essential difference between the 12-hour timekeeping method in the night, and the mutual conversion is very convenient. The present invention considers that: For a quantum computer or a photonic computer, if two binary bits are combined by the binary and the three-ary code, The quantum logic network is a reliable, convenient and cost-effective way to realize quantum computers in technology.

The binary and ternary functions are inextricably linked in many fields such as optics, nuclear physics, chemistry, visual psychology, colorimetry, and computer coding. There are many physical or chemical problems in nature that are closely related to the number 3. For example: Substances are classified into solid, liquid, and gaseous; according to the conductivity of the substance, they are divided into conductors, semiconductors, and insulators; atoms are composed of protons, neutrons, and electrons; the visible spectrum can be divided into three bands: high, medium, and low; The substance has three states: solid state, liquid state and liquid crystal state. The fraction of 1/3 is accurate in 3 decimal. For binary, the result is an infinitesimal number. Obviously, the material world and the number 3 exist. The essential relationship; the quantum world and the number 2 are also closely related, for example: It can be seen from the Liu's segmentation equation that a color in the visible spectrum can be divided into two parts, white and color, and the charge has positive and negative charges. 2 kinds, people have men and women, animals are divided into male and female; there are still complexities between vertical and horizontal crossings between numbers 1, 2, and 3. Only a man and a woman get married to have children or daughters, the smallest of the three individuals is a happy family, in order to continue to reproduce, no 1 no 2, no 2 there is no _3; a color on the spectrum It can be decomposed into three primary colors. On the contrary, three equal energy primary colors can be synthesized into one unit of white, and any two of the three primary colors of red, green and blue are combined to become cyan, magenta, yellow, etc. Complementary light

So many examples show that quantum computing is inseparable from binary and inseparable from the ternary.

The multi-qubit calculation logic given by the present invention covers the following principles:

 (1) The principle of 6-point positioning of microscopic quantum space:

That is, it must constrain its three linear motion degrees of freedom and three rotational motion degrees of freedom. For example, an unknown quantum state output by a CCD camera is composed of two parts: classical information and quantum information. Particles can have six degrees of freedom. : 3 degrees of freedom of linear motion and 3 degrees of freedom of rotational motion, 6 constraints must be applied to make it in a stable position. If there is a constraint or more than 6 constraints, the spatial position of the particle is uncertain. In order to impose constraints on these six degrees of freedom, it is possible to appropriately select six quantum spectral radiation measurements in the visible spectrum to obtain three peaks of three peaks [X _r , Y _r , Z _r ], [X _g , Y _g , 3⁄4], [X _b , Y _b , Z _b ], [Xc, Y _c , Z [X _m , Y _m , Z _m ] and [X _y , Y _y , Z _y ], and then the six sets of data are stored as data states for use as standard data for quantum computing.

(2) The three-point support principle of four-dimensional space-time: The unknown quantum state must also be exactly positioned in 4D space-time. The invention selects three calibration points to form a support plane for placing 3D images: Measuring background state in black background state The three-shot excitability value [X _back . _k , Yback-k, Z _back . _k ], the background value of the white background is measured in the white background state [X _back .w, Yback-w, Z _back . _w ], According to the color temperature of the white light illumination used in the observation of the quantum state, a set of standard white three-shot excitation values [X _w , Y _w , Z _w ] (for example, D65 standard illumination) are determined, and the three groups of three are The stimuli are also placed in memory as shared known data for the sender and receiver. In order to get an exact quantum state in the four-dimensional space-time, the 9-point positioning requirements including (1) and (2) must be met.

 (3) Determining the minimax principle of the space in which the quantum is located: This principle implies the selection of large-scale logic of 0-Θ-1. In order to obtain deterministic quantum calculation results, it is necessary to follow the sub-invention 2-3) The method determines a subspace in which an unknown quantum state XYZ is located;

 (4) Complementary color principle and binocular parallax principle: The Liu's binocular complementary parallax equation given in sub-invention 4 embodies the digital logic of quantum addition, (1 primary color quantum + 1 interchromatic quantum) = 1 red Primary color quantum + 1 green primary color quantum + 1 blue primary color quantum = 1 white light quantum reflects the physiological-physical basis of 2-3 binary interchange coding. Perceiving the world with binoculars is a universal feature of advanced organisms. The material state 3 is the objective existence of visual observation. The information exchange between human and nature naturally links the number 2 and the number 3, especially in the field of artificial intelligence. What people think about is not only the limit states of 0 and 1, but also the consideration of the state of Θ between 0 and 1, that is, more attention is paid to the three states, but 2 is not a factor of 3, and it is unable to solve the complex problems of the microcosm, so The convenience of technology implementation and the complexity of brain thinking should be considered together. When it comes to the operation of quantum computing, the description of the program, and the control of performing complex calculations, it should be done by a classic binary computer. These memories and quantum operators are handed over to the arithmetic logic based on the ternary quantum.

(5) The inverse square law of light propagation: It means that the intensity of the light wave is inversely proportional to the square of the propagation distance. The present invention uses the gamma correction function of the Liu's two-image mapping equation to make the amount of white light _Pw contained in the unknown quantum state XYZ. The correction is obtained, and the constraints of the white light quantities p _w , p _u , ^ are used to pave the way for the space-time traversal of the primary color quantum state by means of the Liu's pipeline function, so that the unknown quantum state XYZ can further overcome the stagnation after getting rid of the "uncertainty relationship". The implicit law imposes implicit recession and distortion on it.

 (6) Principle of NMR and acousto-optic modulation principle: The invention uses the assistance of Liu's pipeline function to map the quantum state of the primary color photon to the "grey kernel" of the Liu's quantum state coupling equation, so that the unknown quantum state XYZ is displayed. The space maintains a determined wave-particle duality relationship.

 (7) The Liu's principle that an unknown quantum state can be completely replicated.

2) Quantum computational logic of multiple qubits

Based on the understanding of the logical relationship between three numbers 1, 2, 3, etc., the present invention constructs a quantum computer (or photonic computer) using a combination of binary and ternary encoding and decoding digital logic, in order to achieve technical For the purpose of easy implementation, it is necessary to make certain memories and operators of the computer quantized, that is, the quantum bit data is encoded in 3, and then the binary code is converted into a binary code, which is composed of the classic 2 The binary computer performs complex calculation tasks and completes tasks such as operation instructions, program descriptions, and program control. Therefore, the core part of the computer is a binary code, and the execution part is a binary code. The specific method of the present invention is: Each byte of the system is defined as 9 bits, each square pixel is specified as 18 X 18 = 324 cells, the word length is specified as 27-81 bits, and the gray level of the image is specified as 324, at this time, 10 Binary 324 = 3 ⁴ X 2 ² , binary 324 = 101001100, binary 324 = 111000, 324 factors are 2 and 3, and Liu's positive quantization equation and Liu's inverse quantization equation a large amount Bit calculation logic is completely consistent. Accuracy of Quantum Computation The present invention is described by the Liu's resolution formula shown below, with a resolution of N _def , and the accuracy of the quantum calculation is related to the change in the number of cycles n:

N _{def =} 3 ²ⁿ *2 ² π = ί,2,3,4 ···

The present invention refers to the formula shown above as the Liu's quantum computing logic, where: the subscript def indicates that the number N _def is a resolution data expressed in decimal numbers, where n is the number of fields, which can only be taken Integer, can not be consecutive values, select the number n according to the resolution requirements, for example: At present, for the video image, let n = 4 is enough, if it is a radar image, it is necessary to select a larger value of n. Where: 3 ² represents the number of bits per three-byte byte, and 2 ² is needed to accommodate the inverse square and 2-3 conversions.

8) Implement the main digital logic circuits of quantum (and photon) computers:

As long as the "big choice" digital logic circuit, gamma correction circuit and matrix conversion circuit (or optical path) are applied to the quantum computing network, it is possible to efficiently implement between binary, ternary and decimal The conversion becomes a practical high-speed computer.

Fourth, the description of the drawings

 Fig.1 Naked hologram 4D TV image quantum communication and display quantum logic diagram.

Five, specific implementation

The computational logic and specific implementation of the quantum communication and display of the naked-view holographic 4D television image will be described below with reference to fig.

In the first step, the RGB color data is converted into data represented by XYZ using the following matrix equation:

Step 2: normalize the unknown quantum state XYZ: that is, the tristimulus value ΧΥΖ three numbers are calibrated to the white point tristimulus value X _W Y _W Z _W , the second step: the unknown quantum state XYZ is returned One treatment: that is, the tristimulus value XYZ three numbers are scaled to the white point of the tristimulus value X _W Y _W Z _W , ί lead XQYOZO: let χ. = χ/%, y ₀ = y/y _w > z. = z/z _w Step 3, use the large-select small logic circuit to determine XoY. Z. Among the minimum and maximum values, the type of Liu's partition equation is selected according to the following rules: If Χο is the minimum value and Ζο is the maximum value, then the 氏 ΧΥΖ is divided by the Liu's partition equation in the p _u g _u b _u format; If Y. Is the minimum value and Xo is the maximum value, then the XYZ is segmented using the Liu's segmentation equation in the ^13⁄4 format; if Zo is the minimum and Y. Is the maximum value, then the simultaneous equations in the p _u g _u bu format are used to segment XYZ, and the values of p _u , g _u , b _{u are} calculated. For the sake of simplicity, the path of ₉ „, ^ and ^ is calculated by using the Liu's partition equation in the pug _u b _u format as min=Xo and max=Zo as an example. When calculating the parameter b _u , the square root is involved. Calculations can be performed using standard gamma correction circuits, and so on for the other two cases;

In the fourth step, the value of the transmission parameter Θ can be calculated by using the g _u and b _u data obtained in the third step by letting sin 0 = YR, cos Θ, cos 0 = YR

For the calculation method, see sub-invention 1-4);

In the fifth step, the calculated Θ and p _u are AD-converted, and then the binary digitized information of Θ and p _u are transmitted to the receiving end; and in step 6, the digital codes of the Θ and _Pu of the receiving end are error-corrected. Error and convert the corrected binary code to DA conversion to obtain the analog quantities of parameters 6 and ^;

In the seventh step, the data is de-coherently corrected according to the method given in the sub-invention 7-1). For the sake of convenience, the corrected white amount data is still represented by p _u ;

In the eighth step, the phase angle Θ data is de-coherently corrected according to the method given in the sub-invention 7-2). For the sake of convenience, the corrected phase angle data is still represented by Θ;

Step 9, according to the method of sub-invention 8), recover the tristimulus value XYZ;

In the tenth step, the photographing tristimulus values XYZ obtained in the previous step are respectively placed in the p _v g _v b _v type, p _v r _v b _v type and p _v g _v type Liu's two-image mapping equation given by the sub-invention 9 respectively. At the left end, the corrected phase angle 得到 data obtained in step 8 is divided at the right end of the Liu's two-image mapping equation;

Step 11, solve the Liu's two-image mapping equation, that is, obtain the base motion value of the holographic 4D TV image [r=e, g, b], [r, g=9, b] [r, g, b=9 ], directly use r, g, b to drive the display to display 4D TV images.

Correction page (Article 91) ISA/CN

Claims

WO 2014/121524 , — ,, PCT/CN2013/071598

A method for realizing a quantum computer, a quantum communication, and a 4D naked-view holographic television system, wherein: 1) the invention only needs a single CCD camera to capture scenes, process image information with quantum computer scene information, and use quantum The communication method of transmitting images and using TFT LCD liquid crystal display constitutes a fast and practical 4D naked-view holographic television system, 2) a new method of creating a quantum light wave XYZ; 3) creating a way to determine by "observation" The method of quantum space; 4) the method of normalizing the unknown quantum state XYZ in inverse space; 5) Creating a method for generating binocular complementary parallax images in accordance with the principle of visual physiology; 6) Creating a _Pw r _u g _u b _u method of thinking color space; 7) pointed out the shortcomings of Copenhagen's interpretation of "wave pack collapse", and proposed a method of interpreting and verifying the correctness of new interpretations of Liu's sound and light different from Copenhagen's interpretation; 8) Denying the classic "uncertainty principle" and "quantum non-cloning theorem", while pointing out the incompleteness of the De Broglie wave model, a new set of descriptions is proposed. Wave-particle duality model, which includes the clamped brightness model for quantifying wave dynamics, the Liu's wave model and the clamped basis color quantity model for quantifying particle properties, and the photon basis color quantity model; 9) Creating an exclusion "decoherence" The method of destruction, which achieves the purpose through the Liu's white clamp equation and the Liu's three-primary clamp equation; 10) creates a phase-modulated light wave into a spatial intensity modulation by copying the quantum state, and then displays A comprehensive approach to 4D holographic images; 11) Creating a method for implementing quantum computers in technology;

2. A method for performing normalization processing of particle information and quantum information of the unknown quantum state XYZ by using the Liu's segmentation equation according to claim 1, wherein: 1) the positive and negative Liu's segmentation equations In the middle, the maximum triplet value of the standard white light is set to the data state for automatically measuring the particle property, and the white light data is quantized by the white amount parameter p _w ; 2) the parameter is used in the Liu's segmentation equation (1 p _w Establishing entangled states between white matter and elementary particles such as red, green, blue, cyan, magenta, yellow, background black, background white, etc., and normalizing the data of these basic particles to further construct quantization The equation is prepared; 3) The Liu's segmentation equation is used to divide the visible spectrum into three sub-gamuts, which is the key measure to determine the space of the photon by observation; 4) The maximum triad of the nine basic photons by the Liu's partition equation Set to the data state, the visible spectrum generates 9 basic entangled states in the positive and negative spaces respectively, creating conditions for completely copying the unknown quantum states; 5) White ginseng generated by the positive and negative partition equations _Pw and the primary volume parameter _{r u, g u, b u} ; 6) is provided four kinds of the quantum parameter 9 standard data state and _{"u, g u, b u,} p w other quantum states that the present invention is unknown quantum states XYZ The unique method of "space-time crossing" is provided; 7) Dividing the visible spectrum into three bands of high frequency, intermediate frequency and low frequency, and dividing the complete color space into three sub-color spaces by using the Liu's partition equation, they are respectively The p _u g _u b _u subspace, the p _u g _u b _u subspace and the p _u g _u b _u subspace are the unique methods for the present invention to provide "space-time crossing" and "state coexistence functions" for the particles; PwXw, PwYw, p _w Z _w ] automatically extracting the white amount p _w contained in the unknown quantum state XYZ is a unique method provided by the present invention;

 3. A Liu's quantization equation for implementing the positive and negative spaces of claim 1, characterized in that: 1) further transforming the unknown quantum state XYZ into 9 data states based on the forward and reverse Liu's segmentation equations. The quantized superposition state represented by the phase angle ,, so that the wave-particle duality data of the photon can be quantified by deterministic data; 2) The Liu's quantization equation of the positive and negative space can describe the "tunnel crossing" of the basic photon. (or time-space crossing) and "state coexistence" characteristics; Liu's quantization equation gives a variety of entangled states and forms multiple qubits. Liu's quantization equation can accurately and accurately describe the "particle-particle two-image" of microscopic particles. "3" The positive phase of Liu's positive quantization and Liu's quantized inverse equation is exactly the opposite. The three sets of triple-excited values provide a stable support plane for the four-dimensional quantum space. Without one of them, the quantum space is also unstable. 4) Comprehensive consideration of the potential relationship between quantum computing and quantum superposition and actual physical state; 5) Provides effective technical implementation for constructing multi-qubit quantum computing logic networks The current approach also lays the foundation for the establishment of Liu's p-rgb four-dimensional vector space, implementation of white light quantum communication technology, and naked-eye holographic television images. 6) Liu's quantized positive and inverse equations are a kind of quantum entangled state generation technology. And sub-gamut segmentation technology, the use of these two features is conducive to the realization of parallel processing technology of quantum computing, greatly improving image processing, transmission efficiency and display quality of multi-dimensional images, but the cost is reduced;

4. A method for determining the space of a quantum by "observation" according to claim 1, characterized in that: 1) the method embodies the fact that the unknown quantum state XYZ can be synthesized by two basic colors and one white; 2) The method finds the space by judging the maximal and minimum values of the three-shot excitability value; 3) determining the normalization operation of the XYZ data before the judgment; 4) the method can use the large-decimal digital logic The circuit is implemented quickly; 5) By comparing the relative sizes of the normalized triple 剌 XYZ, it is possible to determine the subspace in which the unknown quantum state XYZ is actually located, which is a unique method provided by the present invention; 6) Liu's quantization The equation considers that two different background states and the illumination states used to observe the quantum space are sufficient and necessary conditions for the stability of the quantum space, thereby systematically summarizing white light with red, green, blue, yellow, magenta and blue. Quantum entanglement between positive and negative spaces between photons The relationship provides an effective technical implementation path for constructing multi-qubit quantum computing logic networks. It also lays a foundation for the establishment of Liu's prgb four-dimensional vector space, implementation of white light quantum communication technology, and naked-view holographic television images.

5. A method for generating binocular complementary parallax images in positive and negative spaces according to claim 1, wherein: 1) the method is based on Liu's positive and negative quantization equations and is derived from Liu's binocular complementarity. Parallax equation, in addition to inheriting the characteristics of Liu's positive and negative quantization equations, this equation also develops its own unique characteristics; 2) Liu's positive and negative quantization equations make binocular parallax data in each subspace with time The coordinate p _w changes dynamically to generate dynamic, naked-view 3D images. This feature supports various 3D displays to display 4D images. 3) In the Liu's binocular complementary parallax equation, the three eyes are provided for the right eye. The value contains the quantum states of three kinds of photons, red, green and blue. The "grey nucleus" in the coupling state of the quantum state and the Liu's quantum state is a complementary entangled state; 4) the binocular viewing of the macroscopic world, by analyzing the binocular parallax Functional interpretation of the microscopic quantum world, using the Liu's binocular parallax equation to fuse the three-dimensional macroscopic world into the human subconscious, and then using the Liu's quantum state coupled equation to realize the nuclear magnetic state of the primary color and the nuclear magnetic nucleus Resonance, the purpose of replicating the original image in the "parallel world", is a unique method provided by the present invention; 5) This method provides a model for the visual physiology of the binary algorithm logic; 6) can separate red and green Three kinds of single photons of three kinds of photons; 7) positive and negative space Liu's binocular complementary parallax equation structural difference is mainly reflected in p _w and (1 p _w ) transposition;

6. A method for generating a Liu's p _w -r _u g _u b _u 4D color space according to claim 1, characterized in that: 1) Liu's p _w -r _u g _u b _u 4D color space is utilized The four-dimensional space-time coordinate space established by the parameters of p _w , r _u , g _u , b _u calculated by Liu's partition equation; 2) The white quantity _Pw has multiple functions, including: the interpretation of the "wave packet collapse" as a time coordinate; Liu's visual depth model D _u = (1 _P _W )/P _{W is} used as a parameter to control the visual depth of the image; the transformation with relative depth D _u makes the image dynamic in the depth direction; _Pw transmits image information; uses p _{w to} realize quantum communication; p _w realized using holographic display a stereoscopic image; corrected using p _w decoherence damage; volume parameter p _w with white light holographic achieve stereoscopic image display;

7. A method for transmitting an unknown quantum state XYZ using white light amount p _w and phase angle 为了 in order to implement claim 1

1) is a method of transmitting a triple excitation value XYZ by transmitting a white light amount p _w and a phase angle ;; 2) the transmission process includes steps 1 to 7 described in the sub-invention 6;

 8. An interpretation and verification method for "wave packet collapse" invented in order to fully implement claim 1, characterized in that: 1) through actual observation and calculation, "Why does the wave shrink?" Where did the ingredients that existed before shrinking and disappeared after shrinking go? "The long-term suspense of quantum science, the cause of wave-collapse collapse is detailed in the specification; 2) The uncertainty relationship "becomes a deterministic relationship", turns the inaccurate "probability interpretation" into an accurate algebraic operation result, and turns the "quantum state non-cloning theorem" into "the natural world allows people to strictly copy an unknown quantum state." Liu's Cloning Theorem", which lays a solid foundation for the construction of multi-qubit quantum computing logic networks; 3) points out the probability interpretation of Copenhagen's wave packet collapse in quantum science, "the principle of uncertainty", "quantum state The non-cloning theorem "is an incomprehensible interpretation, theorem or model; 4) An interpretation of Liu's acousto-optic light that correctly explains the cause of wave packet collapse; 5) The three-shot excitation value of the red-photon spot is measured The analysis of Liu's primary color clamp equation verifies the correctness of Liu's acousto-optic interpretation. 6) The comparison between the Liu's wave model and the De Broglie wave model demonstrates the error between the uncertainty relationship and the non-cloning theorem of quantum states. Deriving the "deterministic relationship" and "quantum state cloning theorem" of the present invention for wave-particle duality;

9. A method for performing the purified white light amount _Pw and phase angle 权利 according to claim 1, characterized in that: 1) the cause of the wave packet collapse given by the sub-invention 7 is the Liu's white clamp equation and Liu's three The base color phase angle clamp equation purifies the white light amount p _w and the phase angle Θ;

2) The format of Liu's white clamp equation is given, and the method of purifying the white light amount _Pw by the Liu's white clamp equation at the receiving end is invented;

3) Prove the correctness of Liu's acousto-optic interpretation with the derived model of the white clamp equation; 4) Give the format of the Liu's three primary color phase angle clamp equation and its derived model and correct the red, green and blue primary color components. 5) Purification of the phase angle is carried out in three bands of high, medium and low; 6) The correctness of Liu's acousto-optic interpretation is proved by the Liu's trichromatic phase angle clamp equation and its derived model;

10. A method for recovering a triple exciter value XYZ at a receiving end according to claim 1, wherein: 1) substituting the purified white amount p _u and the phase angle 刘 into the Liu's quantized positive equation, It is possible to recover the data of the unknown quantum state XYZ; 2) If the object involved is in the antimatter space, then the Liu's quantized inverse equation can be used to recover the unknown quantum state XYZ.

11. A method for mapping a corrected white amount p _u to a receiving end white amount ρ _ν in accordance with claim 1 wherein: 1) This is a method of transferring a quantum state by establishing a pipe function between the white amount p _u at the photographing end and the white amount p _v at the display end;

2) The format of the pipeline function is: p _v = p · ' 3) The method is completed in 3 steps: calibration of the working state of the camera, calibration of the working state of the display, and data fitting;

12. A method for displaying a 4D holographic image by using a Liu's quantum state coupling equation and a normally black LC-SLM display according to claim 1, wherein: 1) from the Liu's gamma correction equation to the Liu's quantum state The evolution method of the coupled equation; 2) Using the pipeline function to establish the quantization function for the gray kernel parameters of the Liu's quantum state coupled equation and traversing the quantum states p _u and 拍摄 of the shooting space into the display color space, thereby making Liu's gamma The Markov equation evolves to the Liu's quantum state coupled equation; 3) The Liu's quantum state coupled equation has multiple functions: it has acousto-optic modulation function; it can convert the spatial phase modulation of the wavefront from the left end to the right end of the ", g, b space Intensity modulation, realizing the display of the naked-view 4D holographic image; enabling "g _v ', b _v ' and " _u , g _u , b _{u to} form a nuclear magnetic mapping or a two-image mapping relationship with each other; having a gamma correction function, which can eliminate the inverse The influence of the square law on the intensity of light waves; 4) The coupling equation of Liu's quantum state shows that the parameters [λΧ, λΥ, λΖ] are descriptions of the duality of unknown quantum state wave particles; the parameter [p _w Y _w (xt/y) _t ), pwYw, PwYw(l-xt-yt)] is a description of the amplitude and phase holographic information; the parameters [p _w X, PwY, p _w Z] are descriptions of the acousto-optic modulation characteristics of the microscopic particles, and also illustrate The parameter p _w , the parameter λ and the gray kernel parameter are equivalent; 5) Based on the quantum state cloning conclusion given by Liu's acousto-optic interpretation, the Liu's quantum state coupling equation can quantum the three primary color photons The state is perfectly mapped to the right end of the Liu's quantum state coupled equation; 6) The computational logic of binary and binary blending is a good property for solving artificial intelligence problems;

13. A method for displaying a 4D holographic image on a normally white type computer display in a normally white type TFT LCD liquid crystal display according to claim 1 The inverse equation of Liu's quantum state coupling equation and the method of displaying 4D holographic image by normally white TFT LCD liquid crystal display; 2) Using the pipeline function to establish the quantization function and the shooting space for the gray kernel parameters of the inverse equation of Liu's quantum state coupled equation The quantum states p _u and Θ traverse into the display color space, thereby causing the Liu's quantum state coupling equation to evolve to the inverse equation of the Liu's quantum state coupled equation; 3) The Liu's quantum state coupled equation also has multiple functions: with acousto-optic modulation Function; capable of transforming the spatial phase modulation of the wavefront from the left end to the right end of the ", g, b spatial intensity modulation, to achieve the display of the naked-view 4D holographic image; enabling rg _v ', b _v ' and r _u , g _u , b _u constitutes a nuclear magnetic map or a two-image mapping relationship; has a gamma correction function, which can eliminate the influence of the inverse square law on the intensity of the light wave;

 14. A method for implementing a quantum computer in accordance with claim 1 for constructing a multi-qubit calculation logic, characterized in that: 1) the present invention proposes the following multi-qubit calculation logic as follows: Principle: Six-point positioning principle of microscopic quantum space; 3-point support principle of four-dimensional space-time; Determination of the minimax principle of space where quantum exists; Complementary color principle and binocular parallax principle; Acoustic light modulation using anti-square law of light propagation Method; Principle of NMR and principle of acousto-optic modulation; Method of transforming spatial phase modulation into spatial intensity modulation by quantum-state coupled equation; principle of being able to be completely copied by an unknown quantum state; 2) Fusion of binary and 3-ary Up, we give a quantum computing logic that can be perfectly implemented in technology. 3) The binary logic of binary and ternary is given. The format of Liu’s quantum computing logic is :

N _def = 3 ²ⁿ * 2 ^{2 In the} left formula, π = ί, 2, 3, 4 ··· _{; The} index η can only take an integer, can not take values continuously, and select the number η according to the resolution requirements. The specific method for realizing quantum computing digital logic is: specify each byte of the ternary is 9 bits, each square pixel is specified as 18 X 18 = 324 cells, and the word length is specified as 27-81 bits, if The gray level of the image is specified as 324, that is, the resolution is 324. At this time, 324 ₍₁₀ ) = 3 ⁴ Χ 2 ² in decimal, 324 = 101001100 in binary, 324 = 111000 in binary. The factors of 324 are 2 and 3, which is in complete agreement with the multi-qubit calculation logic of Liu's positive quantization equation and Liu's anti-quantization equation. 4) Provides an inexpensive and practical method for technically implementing quantum computers; 5) Applying "single choice" digital logic circuits, gamma correction circuits, and matrix conversion circuits (or optical paths) to quantum computing networks It is able to inherit the existing technology of producing classic computers, and efficiently realize the conversion between binary, ternary and decimal, and become a practical quantum computer.