You mean besides
Some of the things we are working on…
- Quantum Mind, Brain, Consciousness, Cognition & Holonomic Brain Theory
- Quantum Chaos
- Quantum Logic
- Temporal Quantum Logic
- Hyperdimensional Computing
- Classical (Deterministic & Nondeterministic) Reversible Computing
- Quantum Probability
- Quantum Bayesianism
Why are we working on these things? Why not Quantum Computing specifically?
Well, we have the worlds first billion qubit infinite precision circuit based quantum computers. we have billion qudit infinite precision photonic quantum computers. and we will put our quantum gravity quantum computers in production very soon. So what everyone dreams about doing is a direct incremental consequence of the above. They do it because they don’t have a quantum computer of any consequence.
We are focussed on applying our Quantum Computers to solve the worlds problems. Which includes reversing climate change, curing 8000 diseases etc.
We are simulating large plank scale simulations of quantum gravity and trying to create the ‘second’ theory of everything.
What we do is so far ahead of everyone else that we call them 3000 BC pseudo science.
Now lets see what we mean by the terms mentioned above
Quantum Mind, Brain, Consciousness, Cognition & Holonomic Brain Theory
The quantum mind or quantum consciousness is a group of hypotheses proposing that classical mechanics cannot explain consciousness. It posits that quantum-mechanical phenomena, such as entanglement and superposition, may play an important part in the brain’s function and could explain consciousness.
Quantum cognition is an emerging field which applies the mathematical formalism of quantum theory to model cognitive phenomena such as information processing by the human brain, language, decision making, human memory, concepts and conceptual reasoning, human judgment, and perception. The field clearly distinguishes itself from the quantum mind as it is not reliant on the hypothesis that there is something micro-physical quantum mechanical about the brain. Quantum cognition is based on the quantum-like paradigm or generalized quantum paradigm or quantum structure paradigm that information processing by complex systems such as the brain, taking into account contextual dependence of information and probabilistic reasoning, can be mathematically described in the framework of quantum information and quantum probability theory.
*** Automatski is the front runner in Quantum Computing and hence is in a unique position to research Quantum Mind and Quantum Cognition.
Quantum chaos is a branch of physics which studies how chaotic classical dynamical systems can be described in terms of quantum theory. The primary question that quantum chaos seeks to answer is: “What is the relationship between quantum mechanics and classical chaos?” The correspondence principle states that classical mechanics is the classical limit of quantum mechanics, specifically in the limit as the ratio of Planck’s constant to the action of the system tends to zero. If this is true, then there must be quantum mechanisms underlying classical chaos (although this may not be a fruitful way of examining classical chaos). If quantum mechanics does not demonstrate an exponential sensitivity to initial conditions, how can exponential sensitivity to initial conditions arise in classical chaos, which must be the correspondence principle limit of quantum mechanics?
*** Automatski already has a Non-Deterministic Calculus to describe the functioning of the universe. We are not trying to explain the same using ‘regular’ quantum mechanics.
In quantum mechanics, quantum logic is a set of rules for reasoning about propositions that takes the principles of quantum theory into account. This research area and its name originated in a 1936 paper by Garrett Birkhoff and John von Neumann, who were attempting to reconcile the apparent inconsistency of classical logic with the facts concerning the measurement of complementary variables in quantum mechanics, such as position and momentum.
Quantum logic can be formulated either as a modified version of propositional logic or as a noncommutative and non-associative many-valued (MV) logic.
*** We are trying to mix Quantum Mechanics Principles into Logic
Temporal Quantum Logic
A model of quantum concurrent program, can be used to model the behaviour of reactive quantum systems and to design quantum compilers. Quantum temporal logic, QTL, for the specification of quantum concurrent systems using the time-dependence of events. QTL employs the projections on subspaces as atomic propositions, which was established in the Birkhoff and von Neumann’s classic treatise on quantum logic.
Hyperdimensional computing (HDC) is an emerging computing approach inspired by patterns of neural activity in the human brain. This unique type of computing can allow artificial intelligence systems to retain memories and process new information based on data or scenarios it previously encountered.
*** It is very exciting to have a method which can compute based on memories and fresh data. Automatski will make some breakthrough announcements very soon.
Classical (Deterministic & Nondeterministic) Reversible Computing
Reversible computing is a model of computing where the computational process to some extent is time-reversible. In a model of computation that uses deterministic transitions from one state of the abstract machine to another, a necessary condition for reversibility is that the relation of the mapping from (nonzero-probability) states to their successors must be one-to-one. Reversible computing is a form of unconventional computing.
This article got delayed. And we have already announced our Reversible Computer.
Quantum probability was developed in the 1980s as a noncommutative analog of the Kolmogorovian theory of stochastic processes. One of its aims is to clarify the mathematical foundations of quantum theory and its statistical interpretation.
*** Quantum Probability will allow us to understand Quantum Mechanics better.
In physics and the philosophy of physics, quantum Bayesianism (abbreviated QBism, pronounced “cubism”) is an interpretation of quantum mechanics that takes an agent’s actions and experiences as the central concerns of the theory. QBism deals with common questions in the interpretation of quantum theory about the nature of wavefunction superposition, quantum measurement, and entanglement.
According to QBism, many, but not all, aspects of the quantum formalism are subjective in nature. For example, in this interpretation, a quantum state is not an element of reality—instead it represents the degrees of belief an agent has about the possible outcomes of measurements.
*** This is one of our enquiries into Reality and the understanding of our Reality.