WO2001071661A1 - A quantum system computer - Google Patents

Abstract

The invention relates to a novel computer architecture, and in particular, relates to a quantum system computer, which is based on quantum system and has the function of non-linear parallel compuer system. The four difficulties of the prior art, i.e., the wave envelope dip of the state measure of quantum recessive remote transmission, the quantum dissipation os small system in multiple freeness degree system environment, quantum de-coherent effect and how the quantum solid circuits operating in quantum state under normality (e.g. normal temperature, normal pressure, etc) have been resolved. The change of architecture of Von Neumann, and the expand of the machine languages made of large amounts of '0' and '1' to the languages having 4 x 107 code information has been realized by the invention.

Description

 Quantum system computer

 Technical field

 The present invention relates to a computer architecture, and in particular, to a quantum system computer.

 Background technique

 In the prior art, the functions of the fifth and sixth generation computers are single-information high-speed arithmetic and processing of linear data. They are based on symbolic logic processing, and their machine recognition language is 0 and 1 instruction system. The basic application systems of the fifth and sixth generation computers include machine translation systems, problem solving systems, applied language understanding systems, applied image understanding systems, and applied problem solving systems. The architecture on which they depend includes new von Neumann machines, logic programming systems, function machines, relational algebra machines, abstract data support devices, data stream processing devices, etc., whose material basis is the composition of particles and matter in quantum mechanics. This kind of computer is suitable for the past and presently known inductive information, reflecting the status quo and function orientation; but it does not have the ability to process non-linear information in parallel. The types of objects it deals with are mainly structured and linear logic problems. The operation methods include online dialogue, human-machine dialogue, and cooperative operation procedures. They are suitable for solving problems faced by all levels of society and in various fields in order to improve efficiency and reduce costs. .

 The international application of quantum computers is based on the use of probability wave amplitudes (wave functions) to identify the "particle nature" and "wave nature (superimposed state)" of microscopic particles. The quantum algorithm is a two-particle system in a coherent superposition state i W> = a | 0〉 | l〉 + b> | 0> can constitute 4 different states. In quantum state technology, effective quantum computation must maintain quantum coherence, but the traditional view is that the state of "quantum" has wave-particle duality, resulting in the particle position and momentum cannot have completely determined values at the same time, that is, the uncertainty relationship . In the symmetry theory, the symmetry according to quantum mechanics refers to: the symmetry of substitution and phase symmetry of isomorphic particles, and the substitution reaction occurs between isomorphic particles. Quantum computers, based on the basic theory of quantum mechanics, cannot establish a physical model that overcomes technical difficulties such as quantum wave packet collapse, quantum dissipation, and quantum decoherence under normal conditions (normal temperature, normal pressure, etc.). Even in large research institutions, it is currently impossible to build practical quantum computers.

 There are currently four major technical difficulties in the development of quantum computers in the world, namely: the collapse of wave packets in the measurement of quantum recessive teleportation; the quantum dissipation of small systems in a multi-degree-of-freedom system environment; the quantum decoherence effect; Quantum states run in normal states (normal temperature, normal pressure, etc.).

 How to establish a physical solution to overcome these four technical difficulties is the focus of research in various countries, and it is also the reason why the United States, Japan and other countries cannot apply quantum recessive teleportation technology to nonlinear parallel processing systems.

 Summary of the Invention

To solve the above problems, the present invention provides a quantum system computer. The computer is a computer based on a quantum system and having a non-linear parallel computer system (NLPCS) function. The quantum system computer Based on the past, present, and future of unknown and inductive information, reflecting the situation and proposing problem-solving directions and detailed rules; It has the ability to process non-linear information in parallel. The types of processing problems are mainly unstructured and non-linear problems. Methods include quantum system correlation control, focus on problem-handling procedures, strive for optimal solutions, and support decision-making processes. It is mainly applied to major future events facing mankind, such as: energy development, ecological balance, major natural disasters-earthquakes, floods, and prevention of wars that destroy humanity, etc., to reveal events that cannot be seen by conventional science, expand the perspective and depth of decision makers, and improve Decision correctness. According to an aspect of the present invention, a quantum system computer (QSPC) is provided, including a QSPC nonlinear system (right brain function) and a QSPC linear system (left brain function), wherein the nonlinear system includes a nonlinear Parallel information source 0, classic information measurement transmitter 1, classic information A / D converter 2, serial interface 3, quantum system central processing unit (QS-CPU) 4, quantum state information (QS) A / D converter 5. Quantum state information measurement transmitter 6, parallel interface 7, system bus 8, the quantum system central processor 4 includes a non-linear parallel processing system expansion simulation controller and a quantum system neural network component, said non-linear The parallel information source 0 outputs information to the classic information measurement transmitter 1, the output of the classic information measurement transmitter 1 is connected to the input of the classic information A / D converter 2, and the classic information A / D The output of the converter 2 is sent to the serial interface 3 and the quantum system central processing unit 4. The output of the serial interface 3 is sent to the system bus 8. The quantum state information measuring transmitter 6 and The nonlinear parallel Between information source 0, the quantum state information measurement transmitter 6 and the quantum state information (QS) A / D converter 5, the quantum state information (QS) A / D converter 5 and The two-way connections between the quantum system CPU 4, the quantum system CPU 4 and the parallel interface 7, and the parallel interface 7 and the system bus 8 are bidirectionally connected, wherein the linear system includes Linear system central processing unit CPU 9, random access memory RAM 10, read-only memory ROM 11, D / A converter 12, signal feedback device 13, control system receiving feedback information device 14, adjustment switch input device 15, adjustment switch output Device 16, the control system output information device 17, the output of the D / A converter 12 is sent to the input of the signal feedback device 13, the output of the signal feedback device 13 is sent to the non-linear parallel information source 0, The control system receiving feedback information device 14 receives information from the non-linear parallel information source 0 and sends its output to the adjustment switch input device 15, and the output of the adjustment switch output device 16 is sent to the control system output Information device 17, the input of the adjustment switch output device 16 and the D / A converter 12 are connected to the system bus 8 through a corresponding interface, and the output of the adjustment switch input device 15 is connected to the system bus through an interface. The system bus 8 is connected.

 The material basis of the quantum system computer architecture of the present invention is composed of particles and media in the quantum system. Its function is multi-information parallel processing and non-linear data operation. Its basic principle is that the quantum system self-identifies, self-organizes, and educates information. Processing is based on machine language coded information. Its basic application systems include a neural network system based on a quantum system, a quantum recessive teleportation system, and a nonlinear problem solving system. The quantum system CPU 4 of the computer architecture includes a nonlinear parallel processing system extended simulation controller (NLPCS-XEC) (extended emulator control) and a quantum system neural network component.

The quantum system computer of the present invention establishes the symmetry and unity of the microparticles and the medium, and the mass interconversion technology unifies the "particleiness" of the microparticles and the "volatility" mediated by the medium under the action of the particles to uniformly identify them. The present invention establishes the coherent superposition state technology of particles and medium I particle W> = a | 0> I l〉 + b | 1> | 0>; I 介 W> = a | 0> | l> + b | l> | 0 > Can constitute 8 states. The technical research of the quantum system of the present invention finds that the quantum state is the reflection of the particle nature of the microscopic particles and the fluctuation of the medium in the process of symmetrical unity and mass interconversion, and accurate values can be measured through decomposition or concentration. The symmetry of the quantum system principle of the present invention refers to: the corresponding symmetry of particles and medium. Its corresponding displacement reaction is the mass change of particles and media under certain conditions. The quantum system computer of the present invention has established a physical model that overcomes technical difficulties such as quantum wave packet collapse, quantum dissipation, and quantum decoherence under normal conditions (normal temperature, normal pressure, etc.) based on the research results of the quantum system. Expansion simulation controller of nonlinear parallel processing system of the present invention And quantum system computers, which are practical quantum computers.

 Overview of the drawings

 FIG. 1 is a block diagram showing the structure of a quantum system computer according to the present invention.

 Best Mode of the Invention

 The quantum system computer of the present invention uses the non-locality effect of the quantum system, and divides the information of "original (non-linear parallel information source) 0" into classical information and nonlinear quantum state information. The classical information is transmitted by measurement. Device 1 receives, converts classic analog information into data information in converter 2, directly inputs linear data into serial interface 3, and inputs non-linear data into quantum system central processor 4; "Original (non-linear parallel information source) 0 "The non-linear quantum state information is identified and received by the measuring transmitter 6, and the non-linear quantum state information is input to the (QS) A / D converter 5, and the non-linear analog information is converted into coded information in the converter 5, The object code consists of the following codes:

 Al, A2, A9, AO;

 Bl, B2, B9, BO;

... a total of 4 X 10 ⁷ coded messages.

 The converter 5 processes the non-linear parallel quantum state simulation information into parallel coded information, inputs it to the quantum system central processor 4, combines with the non-linear data transmitted by the converter 2, and processes it in the non-linear parallel processing system expansion simulation controller. It is a binary code of 0 and 1, and is input to the system bus 8 through the parallel interface 7.

 The component 9-component 17 and component 0-component 8 of the quantum system computer architecture of the present invention are combined to have a high-level integration function of the nervous system, and provide people with a model theory of the giant system dependent on the brain, and provide cognition. Scientific model theory, these two model theories are to fill the gap in brain science understanding at this stage.

Connecting the quantum system computer of the present invention to various facilities will show a high degree of intelligence and have the ability to process various types of non-linear parallel information.

1. The main differences between the quantum system computer of the present invention and the fifth and sixth generation computers in the prior art: Features. The well-known fifth and sixth generation computers of the present invention.

Performance difference Single-information high-speed operation and processing of linear data Multi-information parallel processing and non-linear data operation are basically based on symbolic logic processing. Machine recognition quantum systems systematically self-identify, self-organize, and understand knowledge. Languages are 0 and 1 instructions. Processing as the basis, machine language as the basis for coding information, application of machine translation systems, problem solving systems, quantum network-based neural network systems, system applied language understanding systems, applied image quantum remote teleportation systems, nonlinear problem understanding System, application problem solving system, solution system

Computers New von Neumann machines, logic programming systems, non-linear parallel processing systems, extended simulation control structures, systems, function machines, relational algebra machines, abstractors, neural network components for quantum systems

 Data support device, data stream processing device

Particle-based material composition in matter-based quantum mechanics. In the quantum system, the composition of particles and media is mainly based on the past and present uninducted information. The past, present, and future unknown uninduced information functions mainly reflect the status quo and functional orientation. Mainly, reflect the situation and propose a solution to the problem and have the ability to process non-linear information in parallel and the details; have the ability to process non-linear information in parallel

The main processing types are structured and linear logic problems, mainly unstructured and non-linear problems. Online dialogues, human-machine dialogues, and cooperative control of the quantum system of cooperative operations are focused on problem solving methods and procedures. To support the decision-making process to systematically improve efficiency, reduce costs, reveal situations that conventional science cannot understand, and expand decision-making. The perspective and depth of policy makers and the accuracy of decision-making are mainly applied to the problems faced by all levels of society and in various fields. Such as: energy field development, ecological balance, major natural disasters, earthquakes, floods; prevention of wars that destroy humanity, etc.

Differences between the quantum computer of the present invention and the known quantum computer:

Categories Well-known quantum computers Quantum system computers of the invention

The application applies probability wave amplitude (wave function) to microscopic particles. The present invention establishes the symmetry and unity of microscopic particles and the medium, the basic "particleiness" and "fluctuation (superposition mass interconversion technology combines the" particleiness "and states of microparticles) Unified identification of media-mediated "volatility" decomposition under the action of particles

A quantum two-particle system is in a coherent superposition state. The present invention establishes a technical algorithm for coherent superposition states of particles and media (W> = a 10〉 1 l> + b | 1> (0> can constitute 4 kinds of non- | W> = a | 0 > (l> + b | l> | 0>;

 The same state 1 introduces W> = a | 0> | l> + b | l> | 0> can constitute 8 states. Quantum effective quantum calculations must maintain quantum coherence. According to the technical research of the quantum system of the present invention, the quantum state is a state. However, the traditional view is that the state of "quantum" has the granularity of wave micro-particles and the fluctuation of the medium. The duality of the particles and the particle position and momentum cannot be called a unified, mass-transformation process. At the same time, it has a completely determined value, that is, an inaccurate solution or concentration can measure an accurate value

 Relationship

Symmetry according to quantum mechanics refers to: Isomorphism The symmetry of the quantum system principle of the present invention refers to: the displacement symmetry and phase symmetry of the particle theorem, the symmetry of its placement and the corresponding medium. Corresponding to the substitution reaction, it is said that the exchange reaction occurs between identical particles is the mass interconversion between particles and the medium under certain conditions. 'Using a quantum computer according to the basic theory of quantum mechanics, the quantum system computer of the present invention cannot establish a normal state based on the research results of quantum systems Achievements under normal temperature (normal temperature, normal pressure, etc.) have been established. Under normal conditions (normal temperature, normal pressure, etc.), quantum wave packet collapse, quantum dissipation, and quantum regression have been overcome. Physical models of technical difficulties such as coherence effects. That is, the physical model of technical difficulties such as the dry effect. The present invention makes it impossible for a large research institution to establish a non-linear parallel processing system to expand a simulation controller and a practical quantum computer subsystem computer, which belongs to a practical quantum computer.

Claims

1. A quantum system computer comprising a non-linear system part and a linear system part, wherein the non-linear system part includes a non-linear parallel information source (0), a classic information measurement transmitter (1), and classic information A / D converter (2), serial interface (3), quantum system central processor (4), quantum state information (QS) A / D converter (5), quantum state information measurement transmitter (6), parallel interface (7), system bus (8) The quantum system central processor includes a nonlinear parallel processing system expansion simulation controller and a quantum system neural network component, and the nonlinear parallel information source (0) outputs information to the classic information measurement and transmission (1), the output of the classic information measuring transmitter (1) is connected to the classic information A / D converter (2), the output of the classic information A / D converter (2) is sent to the serial interface (3) and the quantum system central processor (4), and the weighted serial interface (3 ) Output to the system bus (8), between the quantum state information measurement transmitter (6) and the non-linear parallel information source (0), the quantum state information measurement transmitter (6) ) And the quantum state information (QS) A / D converter (5), the quantum state information (QS) between the A / D converter (5) and the quantum system central processing unit (4), at the center of the quantum system. A bidirectional connection between the processor (4) and the parallel interface (7), and between the parallel interface (7) and the system bus (8), wherein the linear system part includes a linear system central processing unit ( CPU) (9), random access memory (RAM) (10), read only memory (ROM) (11), D / A converter (12), signal feedback device (13), control system receiving feedback information device ( 14), adjusting switch input device (15), adjusting switch output device (16), control system output information device (17), the output of the D / A converter (12) is sent to the signal feedback device (13) The input of the signal feedback device (13) is sent to the non-linear parallel information source (0), and the control system receiving feedback information device (14) receives the non-linear parallel information source (0). Information and its output is sent to the adjustment switch input device (15), the output of the adjustment switch output device (16) is sent to the control system output information device (17), and the adjustment switch output device (16) and The D / A conversion Input (12), respectively, by a corresponding interface with the system bus (8) is connected, and the output of the adjustment switch input device (15) is connected to the system bus (8) through an interface.