Quantum Theory, Computing and Flight

 
Cinema and aviation, two revolutions that transformed the 20th century, have woven a unique and fascinating bond. Aviation, as a symbol of innovation and freedom, has provided cinema with endless inspiration, while cinema, as a medium of immense cultural power, has shaped our perception of aviation and its relentless pursuit of progress.
Aviation, representing innovation, freedom, and adventure, has served as a wellspring of inspiration for countless stories in cinema. From adrenaline-fueled action films set in the skies to romantic dramas unfolding against the backdrop of long flights, aviation has provided cinema with a diverse range of settings, plots, and unforgettable characters. 
Simultaneously, cinema has shaped cultural perceptions of aviation, often portraying it as a glamorous and exhilarating activity. Cinematic images of heroic pilots and elegant flight attendants have profoundly influenced how people perceive the world of aviation.
Cinema and aviation together have sparked inspiration and innovation  in various fields. Science fiction films have presented futuristic visions of spaceflight, igniting the imaginations of scientists and engineers, politicians and educators.
Cinema and aviation, much like the Age of Exploration and the Renaissance, are distinct expressions of humanity's ceaseless drive to innovate, explore, and transcend boundaries. Aviation, akin to the voyages of the explorers during the Age of Discovery, has enabled humanity to reach new horizons, quite literally, and expand its perspectives. Cinema, like the perspective and art of the Renaissance, has opened a window into new worlds of imagination and creation, shaping our perception of reality. Now, quantum theory represents the new "Age of Exploration", promising breakthroughs in science, medicine, and technology.  Similar to these historical periods, it challenges the limits of our thinking and invites us to envision a future where possibilities once deemed impossible become reality.
The connection between quantum computing and the Renaissance period might seem tenuous at first glance, yet a central point of similarity lies in their emphasis on three-dimensionality as a key tool for understanding the world.
In the Renaissance, the discovery of scientific perspective allowed artists to represent the world more realistically, utilizing depth and three-dimensionality in their paintings. This breakthrough led to a revolution in art, architecture, and the perception of space in general.
Similarly, quantum computing is based on quantum principles that enable the representation of information in a more complex and multi-dimensional manner than classical computing. This ability to process information in such a way opens doors to unprecedented developments in numerous fields, from medicine (developing new drugs) and materials science, from creating materials with enhanced properties to the discovery of new scientific breakthroughs. Just as the Age of Exploration, where 3D, in the sense of mapping the world and understanding its spherical shape, led to the discovery of new places and broadened horizons, so too might quantum computing, with its unique multi-dimensional capabilities, lead us to a new era of discoveries and technological advancements.
Quantum computing is a groundbreaking field that harnesses the principles of quantum mechanics, which is based on the electrons of an atom, rearranged to perform calculations. Unlike conventional computers that rely on "bits" which can only be 0 or 1, quantum computers utilize "qubits''. These qubits can exist in a state of superposition, meaning they can be both 0 and 1 simultaneously. Another unique property of qubits is "entanglement", which allows them to be intimately linked, so that an action on one qubit instantaneously affects all other entangled qubits, regardless of the distance between them.
This computation is carried out in conditions of near absolute zero temperature, which provides the electrons with a stable three-dimensional environment. Their operation within this three-dimensional space allows them to encompass any subject from all angles. The result is that they are capable of creating a perfect representation of reality.  Because of this, some researchers compare the operation of a quantum computer to the operation of the entire universe.
It will be possible to create an accurate picture of the world through them, since their computing units are electrons, like the atomic particles that make up the universe.
The size of quantum computers is growing exponentially. This is due to their fundamental structure, which is based on qubits. Unlike bits in classical computers, which can only be 0 or 1, qubits can be 0, 1, or both simultaneously. This unique property, which allows quantum computers to represent multiple values at the same time, means that as more qubits are added to a quantum computer, the number of possible states increases exponentially. For example, a quantum computer with 3 qubits can be in one of 8 possible states, while a quantum computer with 30 qubits can be in one of a billion possible states.
As a result, the power of a quantum computer is millions of times greater than that of a classical computer. Problems that would take today's supercomputers many years to solve, or that they are not capable of solving at all, can be solved by a quantum computer in an instant.
In the realm of the personal online universe, quantum computing will have a profound impact. Higher quality streaming, coupled with new algorithms for data analysis and machine learning, will enhance the ability of social networks and artificial intelligence applications to understand users and provide them with personalized content. Virtual reality worlds will become far more realistic. Telepathic communication, and even interstellar communication, will become practical.
One of the most prominent areas where quantum computing may greatly assist is in the development of atomic fusion reactors, which produce controlled atomic energy, in contrast to the atomic bomb that releases uncontrolled energy. Already today, such experimental reactors produce, for a very short time, a greater amount of energy than that required to produce it. Such reactors could be used to produce unlimited electricity. Such a fusion reactor could also be used as an engine for aircraft.
In the field of cinema, quantum computing will enable the creation of virtual worlds, animations, and special effects that are far more realistic and spectacular. Films in three-dimensional holograms that look exactly like reality, from a different angle on each side, without the need to use 3D glasses, will be perfected. Autonomous creation of films, whereby the filmmaker feeds a few minimal basic data into the computer, and it uses them to create a long and detailed film, will be easy and impressive.
The development and implementation of quantum computers is already well underway. Governments of superpowers like the US and China, companies like Google and Microsoft, and various research institutes have already established quantum computers with substantial investments. There is intense competition in this field, based on the certainty that whoever dominates this domain will also dominate global science and technology, security and cyber, energy, and economy. The development of metals and medicines, engineering and economic calculations, algorithms and encryption, are some of the immediate areas where quantum computing has the potential to revolutionize.
The quantum revolution is a foreseeable and well-founded process that has passed the experimental stage. The expectation is that by 2030 they will become widespread, and their areas of application will greatly expand, with interaction with them becoming as commonplace as with classical computers.