Quantum Internet

Quantum Internet

Quantum Internet is a theoretical system of interconnected quantum computers, which uses quantum signals to send information instead of radio waves. If implemented, the objective of quantum internet is to eventually supplement the current system of interconnected computers, which share information through classical computing devices, such as standard communication protocols which physically connect networks to geographical location.

Although still in the development phase, quantum internet could have widespread impact in the broad areas. Quantum Internet will most likely become a special branch of the classic Internet, which makes it a solution for very specific applications. In order to emulate scientific quantum physics experiments, remotely advanced quantum computers can be connected to a laboratory or machines. Government agencies can use Quantum Internet technology to pursue more strategic election processes, where voters can supplement the combination. Quantum Internet encryption or cryptography securely send quantum information to better information.

Key features of quantum theory are applied to the quantum internet.

The proposed quantum internet is based on quantum computing, a type of based on the key principles of quantum theory.

Quantum computing - Quantum computing is a viable technique with various academic and private organizations, such as IBM Q Experience and various real world applications used by MIT. It involves sharing information through atomic and atomic levels through quantum channels. Compared to classical computing, it can share information with infinitely high rates and with very few limitations. It is also safer than classical computing.

Qubits- One Quantum allows Internet computers to share quantum information among quantum computers, also called qubits. qubit can not be interpreted with standard hardware and can not be copied or destroyed. It provides a similar purpose in quantum computing to a binary character in traditional computing. The number of quizzes in a particular quantum system determines its processing power. For example, a quantum computer can have 5-qubit processing power.

Superposition - There is no way to broadcast a qubits. Instead, quantum information needs to be shared through two quantum processes, quantum superposition and quantum complication. The superposition is a unique phenomenon in which a quantum system can simultaneously capture many states. In traditional computing, a computer can only be in one position at a time. In the example of quantum computing, for particles, it can mean a particle split, in one sense, and at two places at the same time, but can be equally or effectively.

Entanglement- An Entanglement theory is a phenomenon in which two particles of matter or energy are connected and behave equally even when separated at equal distances. This process is an essential part of teleportation theory and other advanced technologies. Due to the fact that information shared by quantum complication does not require physical distance travel between particles, it has unbelievable effects for computing, because the changes made in one can be applied immediately to the other, By which the processing power or speed can also become obsolete. It can theoretically mean the disappearance of inevitable interception of information, which can lead to safe cryptography opportunities.

Quantum Infrastructure - To keep information, quantum computers should be kept at very low temperatures. In some cases the quant is stored within the superconducting wire.