As the amount of data grows, so does the time it takes for machines to process data. Augmented reality, virtual reality, artificial intelligence, robotics, real-time analytics, and machine learning algorithms all require cloud computing to provide unlimited fast and unlimited computing power and infinite storage space. Interestingly, these have occurred after Moore's Law showed a slowdown in development, and Moore's Law has played a role in almost every major advancement in engineering and technology for decades.
Quantum computing opens the door to cloud computing to the new world
By 2025, the demand for traditional computing functions in the cloud will be so large that cloud computing cannot meet these computing needs. The advent of quantum computing is expected to revolutionize cloud computing. Quantum computing provides massively parallel processing, atomic storage and trial of physical laws rather than external encryption. The cloud will soon be driven by quantum computing, and the software will be written in a whole new way.
Although the concept of quantum computing has been proposed for more than 50 years, the real progress has been in the last five years, and 2017 can be said to be a year of quantum computing.
IBM, Microsoft, Google, Intel, and D-Wave have made tremendous progress this year, and quantum computing is pushing the development of computer performance.
Quantum computing is the quantum state of the Lia atomic example to perform memory and processing tasks. Classic computer-switched transistors encode information into units representing "0" or "1". In contrast, quantum computers themselves use the basic building blocks of atoms such as electrons, protons, and photons, and these examples of subatoms are spin.
According to the laws of quantum physics, it may not be clear whether particles are rising or falling. These subatomic particles possess all of these properties at the same time. This is called superposition. A qubit (a new term called a qubit different from a classical bit) can exist at zero or one at the same time. Superposition allows quantum games to perform multiple calculations at once, rather than in sequential order as in traditional machines. Two qubits can have four possible two-digit numbers (00, 01, 10, and 11) at the same time. These overlays enable quantum to perform multiple calculations at once, rather than in sequential order as with traditional machines.
Quantum computing brings to the user massively parallel processing, which can be analogized to the Grover search algorithm. Imagine a prize hidden in the game behind four doors, you must find the prize with as few doors as possible. Traditional computers need to do more than two operations on average to find prizes because it has to open each door continuously. However, quantum computing can find prizes at once because it can open all doors at once. The number of such calculations is twice that of each extra quantum, so the calculation speed is exponentially doubled. A quantum computer consisting of 500 quantum can perform 2 ^ 500 calculations.
We will write programs in different ways, new programming paradigms and languages, new algorithms, and new ways to write logic.
Quantum computing is thousands of times faster than traditional computing, and Google has announced a quantum computer that is 100 million times faster than any traditional laboratory computer.
Quantum computing revolutionizes our approach to machine learning and artificial intelligence, and will significantly accelerate machine learning. Quantum computers will reduce power consumption by 100 to 1000 times due to the use of quantum tunneling.
Quantum computing will undermine today's Internet security, and it can crack some of today's encryption technologies, such as RSA and ECC, within a few days. In this respect, quantum computing is like the application of discovering the enormous energy locked in an atom. Nuclear fission occurred in 1938, nine months before the start of World War II, and it changed the world. Quantum computing may be an IT equivalent of an atomic bomb. Now, we are racing against time and preparing for modern cryptography to be broken. New security methods allow us to protect data using physical laws rather than using external encryption methods.
Quantum computing cannot be applied to all problems. In some traditional tasks, Chuantong service computers are still more practical than quantum computers. Quantum computing solves emerging business problems such as autonomous vehicle coordination, financial modeling, weather forecasting, and particle physics.
Quantum computing revolutionizes the way in which computer science and logic are handled, and many algorithms will need to redesign and rewrite examples that use quantum computing.