The world inventions: The history and the case of the quantum computer!

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You need to discover the world, and there have been many products in the world, since the very beginning. And there have been new versions and even better products than ever before.

In 1998 Isaac Chuang of the Los Alamos National Laboratory, Neil Gershenfeld of the Massachusetts Institute of Technology (MIT), and Mark Kubinec of the University of California at Berkeley created the first quantum computer (2-qubit) that could be loaded with data and output a solution. Accordingly, the quantum computer is relatively new in the world market. And every product being in the world market should receive attention, interest, desire and action, and that is the AIDA-model which we can use when we should have the availability of just having that. And it is not surprising that it comes from MIT, since this school is in the focus of all frames in the world. And you must have excellent results from the school, the upper secondary school, to be a student there.

Quantum computers perform calculations based on the probability of an object's state before it is measured - instead of just 1s or 0s - which means they have the potential to process exponentially more data compared to classical computers. A single state - such as on or off, up or down, 1 or 0 - is called a bit.

In quantum computing, operations instead use the quantum state of an object to produce what's known as a qubit. These states are the undefined properties of an object before they've been detected, such as the spin of an electron or the polarisation of a photon.

Rather than having a clear position, unmeasured quantum states occur in a mixed 'superposition', not unlike a coin spinning through the air before it lands in your hand.

These superpositions can be entangled with those of other objects, meaning their final outcomes will be mathematically related even if we don't know yet what they are.

Why are we using quantum computers? What are their advantages? They are as follow:

-Perform extremely complicated calculations easily such as extremely large systems of linear equations. Hence, we can use LISREL on them to calculate the effects in the nations economy of doing anything in accordance with a program to a political party!
-Possible to simulate quantum systems not possible on traditional computers.
-Potentially process information thousands of times faster than we are used to on traditional computers.

Therefore, we should use the computers that is in accordance with our needs, and with doing different calculations. We should use the computers that are suitable for the problems that we are facing, and the problems can be of many species, and therefore we need programs to the computers that can solve the actual problems that we are facing. And any study program can just be put down inside a computer, and from time to time we can find the effects on the students, and if they are learning something new from the time periods that they are using the universities and the colleges.

Quantum Information Processing focuses on information processing and computing based on quantum mechanics. While current digital computers encode data in binary digits (bits), quantum computers aren't limited to two states. They encode information as quantum bits, or qubits, which can exist in superposition. Qubits can be implemented with atoms, ions, photons or electrons and suitable control devices that work together to act as computer memory and a processor. Therefore, we can use the computers in more ways than before, and using them in the traditional ways is processing information faster than ever before.


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Sverre Larsen

Kristiansand, Norway


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