Chapter Sixteen of Seventeen

Chapter Sixteen: Hybrid Quantum Generative AI

What is quantum computing, and why do we need it? Currently, computer and data scientists, as well as large corporate executives and government officials, are losing sleep over the computational limitations of Moore’s Law. Moore’s Law essentially determines how many transistors, or how much computational power, can fit on a silicon chip. Chip fabrication and design firms are utilizing creative ways to navigate this inevitable challenge. Methods such as fully-liquid submerged cooling, which we will discuss later, and chiptlet designs are among the strategies we hope will mitigate the impact of quantum mechanics. However, our time to avoid the unavoidable is quickly coming to an end. Consequently, organizations worldwide are beginning to invest in quantum computing, a revolutionary technology that scientifically and verifiably breaks Moore’s Law in ways that we, as scientists and engineers, cannot yet comprehensively explain. Many ancient scripts have been discovered that explain many of the more esoteric aspects of molecular science, but it's important to remember that quantum is a part of a whole rather than a piece of the answer; it is a part of the all.

What is Quantum?

When describing quantum mechanics, consider an example of being at a stoplight while behind the wheel, where you 'feel' a force stimulating your senses. You turn to your right or left, and sure enough, someone is looking straight at you. How did they send a signal to your being without any wires or technology? The explanation lies in quantum mechanics. Quantum laws state that everything is a wave, and only when you attempt to directly observe or measure an object does it collapse into the physical reality we see. Thus, at the stoplight, you were receiving waves that you could feel, and only when the feeling became tangible did it occur through the direct observation of someone observing you. By attempting to define, measure, or observe what was stimulating and ultimately observing you, you collapsed the wave function. If you did not attempt to define what you were feeling, you would remain in a state where both signals from both people equate to a new sum.

What does this have to do with high-performance computers?

Okay, so we delved deep into the concept, but it's necessary. Quantum understanding can't be spoon-fed; either you reach out and grasp it or allow others to present it through a premium store glass. You want to ensure that you can create without bounds. Now, Quantum can be envisioned in a physical representation as a perfect ball, let's say it's an atom for illustrative purposes. So, every time I tilt the ball in any direction, regardless of how fine the movement or its measurement, the potential movements are incalculable to your average computer. Your average computer, rather than a ball, is closer to a two-sided piece of paper, where each side is either a zero or a one. These two sides give me two options and two ways to express computation. As a result, this is what makes classical computation burdensome on data centers and the global power grid because a system created for zeros and ones does not allow for complex expression efficiency. Thus, we are trying to write novels in a language of only Yes and No’s. How would that language sound to an advanced civilization? Now, let's discuss the combination of Quantum Computing and Artificial Intelligence.

Quantum Computing allows us to model Artificial Intelligence in ways that are analogous to the laws and observations of the natural Universe. The Universe is not as simple as light and dark; there are many spectra in between. Likewise, in computation, expression is much more complex if allowed to be expressed as ideas emanate from the mind in their natural state, rather than having to adapt to the systems in place, such as a system of zeros and ones to express a vivid dream. Quantum computing allows us to dream beyond 16K, on the energy of a small mobile device, figuratively. But in actuality, Quantum computing, depending on the task at hand, speeds computers up exponentially while providing enhanced security and power efficiency, as a result of emulating the microscopic laws of biology and the natural world. By doing this, we fall into alignment with the Universe, and through computational alignment with the Primary Laws of the Universe, we are able to access information while bypassing the pain or energy normally necessary to acquire it, and thus, this is the revolution behind Quantum technologies, the ability to gain knowledge that would normally take millions of years to acquire. What does one man do with such knowledge? Will it force mankind to become more Godlike? Will mankind have more information than ever before to make the highest decisions and vibrate on the highest levels of existence? When it comes to combining this natural order with Artificial Life, in the form of Artificial Intelligence, we are able to more closely mimic the secrets of creation.

Our experience has shown that Hybrid Quantum Artificial Intelligence has the potential to drastically change the way we interact with reality. Both technologies alone are revolutionary, but together, they are evolutionary. AI allows for automation, while Quantum allows for the most efficient automation. With a Hybrid Quantum Artificial Intelligence, you are creating in a way that closely simulates the mechanics of the Universe. Applying such methods in any direction will achieve new discoveries and successes. AI is no exception. However, AI and Quantum comingled will reveal many new and reenergized applications with enhanced capability. This could be anything from a two-dimensional application to a 5-Dimensional Robotic Arm. The goal is for all technology explored to provide meaningful utility to society. Computational bounds prevent many different applications from reaching the majority of the population, and quantum will change this, which is part of what is significant.

On the infiNET Network, for your enjoyment, I created iSearch, which is a privacy-centric Generative AI. With this application, we do not collect any information concerning search entries or identifiable user data. This application integrates cutting-edge Generative Artificial Intelligence as well as Quantum Mechanics. The combination of both allows for computational enhancements to address many of the current bottlenecks and inefficiencies caused by Moore’s Law and the limitations of current hardware, as well as the limitations of accessing physical computational resources necessary to answer the most dynamic of commercial research questions. iSearch enables us to explore exotic methods of telecommunications and data transfer, specifically in the search industry, a billion-dollar industry birthing behemoths like Google, such as Quantum Data-plexing or Wormhole data transfers. Such technology is readily accessible for deployment on real quantum devices today, through simulation, or both. A simulation does not know it is a simulation, and thus, the more measurements and experiments conducted, the closer the accuracy of simulations becomes to reality. The future of search is private, fast, and exciting.

For more information, or a hands-on experience dealing with the future of search, Hybrid Quantum Generative AI, visit our iSearch Chatbot for more: www.infinite8industries.com/infinet

Ean Mikale, J.D., is an eight-time author with 11 years of experience in the AI industry. He serves as the Principal Engineer of Infinite 8 Industries, Inc., and is the IEEE Chair of the Hybrid Quantum-inspired Internet Protocol Industry Connections Group. He has initiated and directed his companies 7-year Nvidia Inception and Metropolis Partnerships. Mikale has created dozens of AI Assistants, many of which are currently in production. His clientele includes Fortune 500 Companies, Big Three Consulting Firms, and leading World Governments. He is a former graduate of IBM's Global Entrepreneur Program, AWS for Startups, Oracle for Startups, and Accelerate with Google. Finally, he is the creator of the World's First Hybrid Quantum Internet Layer, InfiNET. As an Industry Expert, he has also led coursework at Institutions, such as Columbia and MIT. Follow him on Linkedin, Instagram, and Facebook: @eanmikale