Quantum Information Science & Computing

Quantum information science (QIS) applies the best understanding of the sub-atomic world—quantum theory—to generate new knowledge and technologies.Through developments in QIS, the United States can improve its industrial base, create jobs, and provide economic and national security benefits. Prior examples of QIS-related technologies include semi conductor microelectronics, photonics, the global positioning system (GPS), and magnetic resonance imaging (MRI). These underpin significant parts of the national economic and defense infrastructure. Future scientific and technological discoveries from QIS may be even more impactful. Long-running U.S. Government investments in QIS and more recent industry involvement have transformed this scientif ic field into a nascent pillar of the American research and development enterprise.

United States National Strategic Overview for Quantum Information Science

The United States National Strategic Overview for Quantum Information Science provides information to government and industry leaders on Quantum information science (QIS) as it applies the best understanding of the sub-atomic world—quantum theory—to generate new knowledge and technologies. Through developments in QIS, the United States can improve its industrial base, create jobs, and provide economic and national security benefits. Prior examples of QIS-related technologies include semiconductor microelectronics, photonics, the global positioning system (GPS), and magnetic resonance imaging (MRI). These underpin significant parts of the national economic and defense infrastructure. Future scientific and technological discoveries from QIS may be even more impactful. Long-running U.S. Government investments in QIS and more recent industry involvement have transformed this scientific field into a nascent pillar of the American research and development enterprise. The Trump administration is committed to maintaining and expanding American leadership in QIS to enable future long-term benefits from, and protection of, the science and technology created through this research. Based on the collective input of all the Government agencies invested or interested in QIS, this document presents a national strategic approach to achieving this goal. Specifically, the United States will create a visible, systematic, national approach to quantum information research and development, organized under a single brand and coordinated by the National Science and Technology Council’s (NSTC) Subcommittee on Quantum Information Science (SCQIS). These efforts will leverage existing programs and approaches, adapt to the changing and improving scientific and technical knowledge, reflect the best understanding of opportunities and challenges in QIS for the Nation, and take new steps where appropriate. The national effort will:

• Focus on a science-first approach that aims to identify and solve Grand Challenges: problems whose solutions enable transformative scientific and industrial progress;
• Build a quantum-smart and diverse workforce to meet the needs of a growing field;
• Encourage industry engagement, providing appropriate mechanisms for public-private partnerships;
• Provide the key infrastructure and support needed to realize the scientific and technological opportunities;
• Drive economic growth;
• Maintain national security; and
• Continue to develop international collaboration and cooperation.

The key next step will be to develop agency-level plans that address the identified approaches and policy opportunities in the next section, which will be integrated into an overall strategic plan. This will enable new opportunities on a ten-year horizon, possibly including: the development of quantum processors which may enable limited computing applications; new sensors for biotechnology and defense; next-generation positioning, navigation, and timing systems for military and commercial applications; new approaches to understanding materials, chemistry, and even gravity through quantum information theory; novel algorithms for machine learning and optimization; and transformative cyber security systems including quantum-resistant cryptography in response to developments in QIS.

Current State

Simplistically the current state, exemplified by the SolREI Studios playlist on this topic, is that we have some pretty incrediable hardware, software, and human capital working in the area of quantum information science and computing. The catch to all of this is that 100% of all that thinking is essentially based on the Encapsulated Interpretative Model (EIM) of M1 and that EIM does not close, nor will it ever, and therein lay a tremendously huge hole in this area of science and industry.

Mode Shifting

What none of these agencies ever anticipated was Elegant Reasonism creating an environment that may mode shift 100% of these efforts to a completely different context requiring a systems review in order to achieve these stated objectives.

Quantum Computing represents an investigation area by the SolREI company to determine the value from industry achievements to date in an effort to identify mode shifted value for potential patent areas. This page serves as a landing page on the subject of Quantum Information Science and Computing and provides an introduction to the various areas for mode shifted articulation of concepts. It should be noted that classical quantum computing is an entrenched M1 concept. Quantum computing is largely an illusion. What the majority industry participants do not realize is that they are operating within M1 encapsulation. They are also oblivious to their commission of Langer Epistemology Errors. The foundation of quantum computing has its genesis with Schrodinger’s Concepts.

Note: The User Library has updated the Information Sciences area specifically on the topic of Quantum Computing which may be referenced for traditional points of view.

Perceived Value

Mode shifting value derivation in this area of industry and science is not for the feint of heart. When we critically look at these various problems in the context of Elegant Reasonism we must separate how they are perceived under the various models. We agree with IBM on scale, quality, and speed. We also agree that value is a function of performance, capability in a frictionless environment (See our QIS&C Playlist.)  While IBM and others define these factors in terms of their respective and realitive solution strategies we want to drop back and ask what the source of those factors are relative to the EIMs instantiating them and to understand that we must mode shift those factors.

• Scale
• Quality
• Speed (e.g. velocity vectors)
• Capability
• Frictionless (as defined by IBM)

However, understanding these factors also requires understanding the source of that value which inturn requires comprehension of the issues represented by the plurality of the EIMs being employed by any given investigation.

(M1)

The promise of quantum computing was first recognized in the 1980s yet remains unfulfilled. Quantum computers are exceedingly difficult to engineer, build and program. As a result, they are crippled by errors in the form of noise, faults and loss of quantum coherence, which is crucial to their operation and yet falls apart before any nontrivial program has a chance to run to completion. This loss of coherence (called decoherence), caused by vibrations, temperature fluctuations, electromagnetic waves and other interactions with the outside environment, ultimately destroys the exotic quantum properties of the computer. Given the current pervasiveness of decoherence and other errors, contemporary quantum computers are unlikely to return correct answers for programs of even modest execution time.

M1 is a logically correct EIM, but its core constructs preclude attaining unification exactly because nothing real may transit the spacetime-mass interface as defined by a fairly famous equation which needs no characterization here. The wave function dismantles when we recognize the implications from The Death of Schrodinger’s Cat. When we recognize that the wave-particle duality is essentially a product of The Fundamental Entanglement Function, limited by Severance the associated manifold equations become inverted (e.g. they become more concerned with the architectures in the frame than the medium of the frame). The issue here is that it changes our perspective of the mechanics of superposition.

M1 QIS&C Challenges

Status quo quantium information science and computing circa 2020 presumes their thinking is tied to reality rather than abstractions of it. They are not considering a simultaneously true alternative manner of contempalating the same set of circumstances.  Consequently they are not prepared to accept, for example, The Death of Schrodinger’s Cat as a logical construct resulting from logic artifacts and Langer Epistemology Errors (LEEs).

qBit

A quantum bit, or qubit, is the building block of a quantum computer. Qubits are different from conventional bits whereby quantum behavior enables a superposition of states (0 and 1) at the same time with varying occupancy probability. What is not known and is being pursued to the confusion of the entire industry are efforts to reduce noise and decoherence issues while maintaining expected speed benefits.

(M5)

The promise of quantum information sciences and computing dramatically shifts under Elegant Reasonism and The Emergence Model. The speed normally associated with quantum mechanics here is a function of Rapidity and the value ‘c‘ is reassigned representing Severance. The quantum decoherence noted by M1 mode shifts to difficulties associated with the relative and respective dynamic complex composite architectures of mass. And in realizing that paradigm shift we also establish a core value associated with pursuing quantum mechanics (e.g. R&D associated with architectures of mass). What under M1 are perceived as superpositions of states under M5 are probabilities of quantum entanglement by architectures of mass and they do not represent necessarily a multiplicity of states. Rather they represent quantum entanglement influences and they are limited by Severance and those limitations are responsible for the quantum noise and system degradation experienced by research teams worldwide.

Mode shifting paradigms of mass require us to purge traditional point mass concepts and recognize complex dynamic architectures. Knot Theory demonstrates concepts of density and saturation relative to and respective of configurations of MBPs driven by The Fundamental Entanglement Function limited by Severance. The point here is that what appears as one particle in multiple states is actually an illusion of superluminal entanglement from constituent components of that complex architecture. The state changes noted are affected through entanglement by these architectures noted in no other manner exactly due to the aforementioned saturation and density issues. These same issues are responsible for dark matter in The Emergence Model.

Mode Shifting Perceived Value

Working these issues through Elegant Reasonism requires us to necessarily take them through each of Elegant Reasonism’s phases: Recognition, Illumination, and Analysis. As we move through that process & methods we must first realize that perception is going to change as a function of context made manifest by the relative and respective model.

Scale

The only argument we might bring to bear on issues of scale are those resulting from system design which integrates insights from the unified Universe rather than the existing M1 thinking being employed across the industry. We also think that the industry as a whole should support our call for the National Science Foundation to support an information system (likely consistent with the IBM hybrid QC & Classical systems) approach to investigate architectures of mass.

Quality

What current industry researchers do not understand is The Fundamental Entanglement Function, limited by Severance is essentially the source of their noise. Understanding architectural distinctions will help clean that up, but we need a broader more introspective systems review across this domain of discourse and all its various detail sets.

Speed

While speed does remain valuable as a result of an Elegant Reasonism based systems review, the source of that speed shifts from Quantum Mechanics (QM) and to the nature of The Emergence Model itself.

• That promise of speed is actually greater that previously believed because one of the accomplishments made manifest by The Emergence Model as developed by The Emergence Model was deconstructing the limits imposed by rules associated with spacetime. There are no velocity limits imposed by M5 or M6.
  • Rapidity emerges as the governing factor regarding the velocity of light and is the source of perceived speed in quantum computing systems. Rapdity is defined as velocity over ‘c’ and that means the mode shifted definition read properly is: velocity over Severance and the implications are profound.
• The variable ‘c’ shifts its meaning from “the speed of light”, to “the Severance value resulting in the speed of light”. That subtle shift in thinking means that the speed of light is what it is locally because the Severance value associated with the system configurations producing photons are all the same and produce emissions in the same manner. Those characteristics are what are responsible for reflection, refraction, coherence, frequency, and the constituent interactions of electromagnetism.
• The Fundamental Entanglement Function, limited by Severance associated with Photon & Electron Architectures interaction are what is responsible for the particle-wave duality. The only thing that changes is where in the architecture the interaction occurs. The double slit experiments are easily explained in exactly the same manner employing various degrees of entanglement across the constituent gradients of architectures. Have you ever been in an airplane at low altitude and seen the bright circle around the shadow of the plane? It is in essence the double slit experiment inverted. Look at the latest trailers for the movie Top Gun: Maverick and you’ll see it illustrated there. We are also in the process of producing videos through SolREI Studios to illustrate exactly the same thing. The point is that anyone can reproduce those results easily. Reconciling this repositions the concept of superposition in QIS&C.

Capability

Once we comprehend the mode shifted implications of quantum information sciences and computing hardware systems will certainly achieve new capabilities, but the real improvement we expect to come from the software systems leveraging them. Operating systems and application software operating in fully compliant Elegant Reasonism environments will achieve unprecedented capabiities.

Frictionless (as defined by IBM)

Frictionless is essentially an ability to orchestrate resources seamlessly between classical and quantum computing systems and we also agree this will be a necessary element on the path forward.

Value is Architecture Determinant

Right now we know very little about architectures of any particular given mass. We do not because no one knew to look at that as an issue. We do know now and therein lay the opportunity and value. Entanglement through the double slit experiments or in the aircraft experiment can be leveraged in other arenas. The RF “knife edge” propagation phenomena is exactly the same phenomena. There are considerable volumes of information on all of these factors. RF Antennae systems seems a great place to start experimentations.

Schrödinger

We continue to bring the original SolREI systems review notes online. The current status of that effort has each concept title linked from its landing page out to the specific page area in the original systems review notes. Consequently you may click any of the over 400 individual concepts from EMCS01 and then click the main title to be presented with our original notes. Please know that much has been developed since those notes were originally written. Be that is it may we present them to you here.

Concept 0231: Schrödinger wave-function for an un-preturbed system

Concept 0232: Schrödinger Wave-function Energy

Concept 0233: Schrödinger Energy Time-Dependent Operator Equivalence

Concept 0234: Schrödinger wave-function for an Perturbed system

Concept 0235: Schrödinger Equation for Single Particle in a potential

Concept 0236: Two-Body Simplified Schrödinger Equation

Deriving Mode Shifted Value

The value of any investigations by SolREI across this industry economic area should seek patentable materials useful once mode shifted. There may be areas holding such value, despite the fact that SolREI would in effect completely disintermediate economics associated with this industry. Our strategy should be to drive ERCUL licenses and royalties via our insights.

The value mode shifting quantum computing for the company lay in determining relative and respective architectures of mass behaviors and interaction capabilities. Structure equals properties (Proposition 0010) and properties infer intrinsic structure (Proposition 0149).

The Quantum Stack

“The Quantum Stack” is a set of technology areas needed to deliver the concepts of quantum information sciences and computing to the marketplace.

Applications

Quantum applications are those software instructions that leverage the unique computing environment of qBits. qBits are quantum state bits. Natural computing involves zeros and ones. The quantum realm extends that by adding a concept called ‘superposition’. Mode shifting this realm to M5 finds superposition simply entangled constructs driving those state changes. The value derived from this area of the industry lay in explorations of The Fundamental Entanglement Function, limited by Severance.

The question we have now involves extrapolating the previous uses to the new quest. A comprehensive review of prior application code and its employed objectives with the new requirements.

Algorithms

A comprehensive systems review would be required of the various algorithms resulting in mode shifting them relative to their objectives and purposes.

Quantum Programming

Another aspect of any systems review conducted into QC by SolREI should specifically look at adaptations required of the various computing languages in order to accommodate mode shifting.

Quantum Compiler

Quantum compilers seek to recreate the famous benefits achieved by Dennis Ritchey and Brian Kernighan during the development of C programming language by extrapolating their process to the realm of QC. That is to say using quantum programs to create quantum compilers developed on quantum computing hardware platforms.

Quantum Machine Language

The issue is essentially the same and is a function of research into the nature of various architectures of mass employed in the construction of qBit quantum devices.

Quantum Assembler

Assembler languages on any hardware is a study of that hardware and enabling it in computing. QC assembler is no different in that regard. What no one in the industry realizes is that their study is also an inquiry into the architectures of mass manifesting hardware qBits. Therein lay considerable value for SolREI regarding patent applications.

Classical System Control

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Software and Hardware

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Quantum Device

Quantum devices operate in the realm of quantum mechanics employing very small devices at the atomic or sub-atomic level.

Physics Package

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QC Reference Organizations

Joint Center for Quantum Information and Computer Science

QC Vendors

Zurich Instruments

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#ElegantReasonism #EmergenceModel #ModeShifting #EIM #QuantumInformationSciences #QIS #QuantumComputing #QC #QBit #Superposition #Entanglement #Severance