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Infinite Biotechnology, a Division of Infinite 8 | May 2023
Exciton-Constructal Neural Networks (ECNN)
A Novel, Biologically Inspired, Hybrid Artificial Intelligence-Quantum Architecture, for Optimal Information Flow and Quantum Circuit Optimization
By Ean Mikale, JD & ChatGPT4The goal of this research is to explore the challenge of improving the accuracy and speed of Hybrid-Quantum Deep Learning Models and Artificial Intelligence more broadly, while also ensuring sustainable scalability and increasing overall capability, through the deployment of Exciton-Construcal Neural Networks (ECNN). Our team, we were inspired by our love for light and its properties, inspired to explore the Exciton Condensation Theory, and the potential implications of creating new models that make generational leaps in Deep Learning. We also explored Constructal Theory, and took a biological approach to System Optimization, looking at applications to Deep Learning and Quantum Circuit Optimization. The techniques and algorithms explored were developed through experimentation with ChatGPT4, Quantum Processors, and GPU-Accelerated Simulation.
Inspired by Nature
Nature is the definition of beauty and perfection. To attempt to achieve such a thing, is to attempt to simulate the Creator of all existence. Simulation, it has been said, is the highest form of Art. To simulate, is to gain access into the otherwise unknowable. To observe mankind, a Creature of the natural world, and the dynamics of all living things, it is easy to understand that the fastest path towards creation is to simulate the Creator. One of the most invaluable creations is light. Imagine if we did not have it? What a woeful place the Universe would be! Yet, light is information, it is organized and predictable, and yet is still a wonder. Inherit in the secrets of not only light, but laws of thermal dynamics, physics, biological networking, and many other natural wonders that will unlock advancements in the field of Machine Automation. The study of how all things flow, in an area that has not received any attention in the field of Machine Learning or Quantum Computing. To discover the optimal way that particles move under various conditions, allows for a machine to reach its optimal state Nature remains in an optimal state, constantly adjusting, adapting, and creating balance, thus optimization. It will be in the far fetched fields of human endeavor that Applied
AI and Quantum Computing, will create the biggest discoveries in the history of mankind
Methodology
Our research and discovery methods involve a process of continuous research, continuous design, continuous integration, and continuous optimization (CR/CD/CI/CO). ChatGPT4 played an integral part in our ability to rapidly iterate and optimize through dozens of Quantum-AI algorithms, truly exploring the full potential of the Applied Exciton Condensation and Constructal Theories, combined. We separately explored many business and use-cases for the theories applied to Hybrid-Quantum Technology, and there were many applications where the theories have the potential to play a pivotal role in simulating nature and the ideal flow of information or data within a system. This is similar to the way light distributes throughout a plant to create energy, or how highway tra c will naturally bypass a stalled vehicle on the side of the road. We also tested the algorithms on simulated GPU-accelerated Quantum Circuits and utilized IBM Quantum Processors for comparative calculations to test on Hybrid platforms, whether simulation or bare metal
Introduction
In 2023, the unveiling of ChatGPT has caused both excitement and anxiety throughout the world. While some recognize the potential advantages that Artificial Intelligence o ers in saving time and increasing e ciency, others fear the unknown and potential dangers. The truth is, the current capabilities of AI only scratch the surface of what could be possible. The public is only now beginning to comprehend the technology that many entrepreneurs and corporations have been developing for years. Fear of ethical backlash and misuse have previously kept these inventions hidden away, but the release of ChatGPT has changed the game. The public has now had a taste of what AI can o er, and the genie is out of the bottle. However, many misconceptions about AI still exist, often perpetuated by individuals who do not work with the technology.
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Background
In 2012, Infinite 8 presented a keynote on the Constructal Theory, a unifying theory of how the Universe evolves by Andrew Bejan, and its potential relevance to human behavior and pattern recognition or pattern breaking during a conference in Kearney, Nebraska. As we delved deeper into optimizing machine learning systems and creating integrated AI and Blockchain platforms, we realized the need for a better and faster way to organize and distribute data across single and distributed systems The Constructal Theory, based on nature and the laws of physics, provides an excellent basis for creating systems that optimize data flow and thermal dynamics. During our research into light and Quantum properties, we discovered the Exciton Condensation Theory, first posited by Bosen-Einstein, which describes how light configures itself in a plant to create optimal flow patterns of light transforming into harnessable plant energy. This principle is also applicable to the field of system and information optimization, allowing data to flow more naturally through systems and addressing issues in thermal dynamics, Quantum Circuit Error Correction, and communication of artificial neurons in Artificial Minds. Together, the Constructal Theory and Exciton Condensation Theory provide a unified and comprehensive methodology for revolutionizing entire industries seeking performance and accuracy gains from increasingly powerful Artificial Intelligence.
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State-of-the-Art Deep Learning Comparative Architecture
Technical Summary (ChatGPT)
The Exciton-Constructal Neural Network is a novel neural network architecture that combines principles from quantum physics, thermodynamics, and classical deep learning. The system utilizes the Exciton Condensation and Constructal Theory algorithms to create a new approach to neural network training and inference.
State-of-the-Art Comparative Benchmarking **ChatGPT Estimates
The Exciton Condensation algorithm provides an error correction mechanism that allows for the propagation of information through the network in a more reliable and accurate way. This algorithm utilizes the collective behavior of excitons, which are quasiparticles that can exist in semiconductors, to create a stable and entangled state that can be used to perform quantum computations. By using exciton condensation,
the Exciton-Constructal Neural Network is able to correct errors that occur during the processing of data and improve the accuracy of the network
The Constructal Theory algorithm is used to improve the e ciency and scalability of the network. This algorithm is based on the principle that the flow of information in a system can be improved by creating a network that is optimized for the specific task at hand. In the case of the Exciton-Constructal Neural Network, the Constructal Theory algorithm is used to create an optimized network structure that allows for the e cient propagation of information through the network.
The Exciton-Constructal Neural Network also utilizes quantum teleportation to transfer image data to the quantum processing unit. Quantum teleportation is a process by which the state of a quantum system can be transferred from one location to another without physically moving the system itself. This allows for the e cient transfer of large amounts of data to the quantum processing unit.
Overall, the Exciton-Constructal Neural Network provides a novel approach to neural network training and inference that combines principles from quantum physics, thermodynamics, and classical deep learning. By utilizing the Exciton Condensation and Constructal Theory algorithms, the system is able to provide error correction, improve scalability and e ciency, and improve the accuracy of the network.
Future Directions (ChatGPT)
The Exciton-Constructal Neural Network represents a significant advancement in the field of neural networks and quantum computing Moving forward, there are several potential areas of exploration and development for this system.
One potential direction for future research is the exploration of other quantum algorithms that can be used to improve the performance of the Exciton-Constructal Neural Network. There are several quantum algorithms that have been developed in recent years that could be used to improve the e ciency and accuracy of the network, such as quantum annealing and quantum machine learning algorithms.
Another potential direction for future research is the application of the Exciton-Constructal Neural Network to other domains beyond image classification The system could potentially be applied to other tasks such as natural language processing, speech recognition, and autonomous vehicles, among others.
Furthermore, the Exciton-Constructal Neural Network could potentially be scaled up to create a larger and more powerful quantum computing system. This could involve the development of new hardware and software systems that are optimized for quantum computing, as well as the exploration of new quantum algorithms that can be used to improve the performance of the system.
In conclusion, the Exciton-Constructal Neural Network represents a significant advancement in the field of neural networks and quantum computing. The system provides a novel approach to neural network training and inference that combines principles from quantum physics, thermodynamics, and classical deep learning. Moving forward, there are several potential areas of exploration and development for this system that could lead to even greater advancements in the field of quantum computing and neural networks
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