Released: May 9, 2026 8:00 AM CST
Here is the thirtieth episode of Quantum Foam, Quantum Computing. This is the third section of 10 of the podcast. The ability to Quantum Compute will crack all current encryption. This won't crack all encryption forever, though. IBM and Google currently have Quantum Computers. There will likely be updated versions and others with the same technology soon enough. We are using the prevailing logic for Quantum Computing using probability vectors and density operators. The different states can be written using different types of math. Nobody gets this stuff. This stuff isn't meant to be hidden anymore. The standard Cartesian coordinate system is to be assumed for creating point matrices with infinitely many factorization complex numbers. We will be working with computer binary systems. We can use 3 different options or 4 different options for our fundamental parameters. That is for when we are actually programming a Quantum Computer. You have a 1 on the left, an x in the middle, and a 0 on the right. This is a way you can visualize the different parameters. Great attention is taken when describing the qubit that is both an on and an off or an off and an on. There needs to be a tendency to land exactly 50 percent between the value of 1 and the value of 0 built into the programming. There are specific directions of subsets of programming that are important. Then, qubit measurements are done. There are other types of Quantum Computing. There is Adiabatic Quantum Computing. Next, there is one called a Universal Quantum Computer. In other words, A Turing Machine. There are others such as Quantum Circuit Models that use n-bit registers. Quantum Computing is concerned with entanglement and integer superpositions. Quantum Computing will most likely be an extension of the silicon computers that we have now. Silicon isn't going away any time soon. We are able to potentially program microchips that enable the possibility of Faster-than-light Communication. We can currently manipulate both particles and antiparticles on our silicon devices.
We can use different mathematics when describing our physics. We can use a Hilbert Space and set it to a complex inner product space that is complete. This is used in Quantum Mechanics to describe all possible states of a system. We can have a 2D complex vector space for a single qubit or perhaps a square-integrable wave function, depending on the system's dimensionality. We have a 50 percent difference engine with a 1 on the left and a 0 on the right and an x in the middle. There is programming that gives the direction of the information exchange. This is essentially a working 2 state system. There were lots of different people that are said to have contributed to this theory. Information Science is built upon this idea. This is Linear Computer Technology as well as Quantum Computing Technology. This is a linear superposition that can be represented by its 2 orthonormal basis states. In other words, it can be represented by their basis vectors. 2 values are used that are both 2 to the n qubits. 2 to the 2 is equal to 4 values. We have different qubit states. We also have what you can refer to as abstract spaces described by a sphere where the surface area covers the math for 2 states. We are talking about certain positions within a mechanics. These state spaces do not describe literal locations. We are talking about theoretical spin space states. We have the ability to be in a world where we have a smooth transition into an era of encryption that cannot be cracked. We are trying to send 1 qubit between Alice on one end and Bob on another. They are pre-sharing an entangled state in order to make something such as communication work. Quantum Computing is done differently than Classical Computers. The placement of the 1, the 0, and the variable x can be written logically any way. We have chosen to represent our fundamental variables as a 1 on the left, 0 on the right, and an x in the middle. We are describing electronic spins. Why do we need to make sure that our program includes a 50 percent difference engine? Because otherwise the computers would not know how to do it. This is the way around it. The purpose of this science is to surpass the limitations of linear computers. We want to use Quantum Computers to adequately emulate intelligence in the form of real Artificial Intelligence.
Finally, there exists a podcast that covers it all! The Quantum Foam Podcast Show can be thought of as a clever and informative mix between "Bill Nye The Science Guy, Rick & Morty, and The Big Bang Theory!"
It seems the idea of the prestigous 'Theory of Everything' has been in the air lately. Join Dr. Hezekiah Paul Smith as he takes a systematic assessment of Physics, Mathematics, and Science as a whole. This show is an Artificial Intelligence approach attempting to explain ALL scientific phenomena across the board! Listen to some the greatest thinkers of all time during the in-depth evaluation of the natural sciences.
Prepare to enjoy a radical and uncensored podcast, Quantum Foam, featuring characters presented as real, animated A. I. entities. Brought to you by Zerothwave Productions.
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May 9, 2020 2:42 AM EST
Quantum Foam is a new podcast with absolutely ridiculous content covering almost all topics relating to science across the board. The idea of achieving the famous Theory of Everything seems to be in the air lately. Such an idea can then be presented as episodes of Quantum Foam in an audio podcast form that will serve to bond together the very powerful and insightful ideas, concepts, and realizations of Physics as a professional discipline. Unifying Relativity and Quantum Mechanics never seemed so . . . possible? Quantum Foam finds its focus directly pointing at the most accepted scientific thought in this day in the beginning of the Information Age. These areas include String Theory, Loop Quantum Gravity, Einstein's famous General Theory of Relativity, Cosmology, Advanced Mathematical Theory, and much more.
Information technology and innovation are at a point where each presently require a Quantum Leap in order to move forward to the next phase. This process, while imperative, is still quite a sophisticated discipline in and of itself. Many will need to satisfactorily understand Quantum Computing and Uncertainty in general very early on. Why not take such a daunting task and turn it into something fun, provocative, and ridiculous instead? And this can be done while still holding strict guidelines in accuracy and application. Enjoy learning about math and physics in a completely free-form manner with no filters, no agendas, un-cut, and raw! We will not be censoring any vulger cursing or other inappropriate references, yet unwanted racial and sexual references etc. will not be included.
Each episode is exactly 30 minutes long and each follow a standard structure. There is an intro stating the title and topic, followed by the Quantum Foam theme song, Physics of the Future, by H-Wave. Then at exactly 15 minutes into the podcast show, there is a mid-point section to keep the listener fresh and to remind which episode is currently streaming. At the end of the podcast, the last 30 seconds, the standard Zerothwave Disclaimer is played. An expanded version of this disclaimer can be found here.
Zerothwave Productions currently is releasing the show on its own website using its state-of-the-art online waveform player platform. Listen to the podcast at actual 320 kbps .mp3 streaming audio right here at Zerothwave.com! The Quantum Foam podcast will likely also be released elsewhere on other platforms soon as well. XML RSS feeds are an old technology but is still in heavy use today. The Zerothwave.com website will be upgrading hosting servers steadily over the next decade and beyond to bring you the highest quality audio possible. Stay tuned for more content!
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