Quantum Computing Explained Simply – How Quantum Computers Work?

5 mins read
Quantum Computing Explained Simply - How Quantum Computers Work
It becomes extremely interesting when one thinks about the power he has in his pocket. The smartphone's today have the power of military computer from 50 years ago that was used to be of the size of an entire room. However, even after we have made exceptional steps in classical computers and technology since the arrival of quantum computers there have been problems that the classical computers were not able to make up to. Many geeks believe that quantum computers are the answer.

The Limits of Classical Computers

Now, as we have built the switching and memory units of computers that are known as transistors that are almost as small as an atom, but we need an entirely new way of thinking. Despite the fact that the classical computers can help us do many wonderful things, "behind the scenes" it’s a calculator that uses a sequence of bits - 0 and 1 - for representing two states say, ON and OFF. This makes the computer understand and make decisions about the data that we input as a set of instructions. However, the intent of making quantum computers is not at all in context with the "replacement of classical computers" but to solve complex problems that are beyond the capabilities of a classical computer. Basically, we are heading to enter in a big data world in which the information that we need to store grows, there would be a need for more ones and zeroes and the transistors to process it. For most of the part, the classical computers are limited to doing one thing at a time and the complex the problem becomes, the longer it takes. Any problem that requires more power and time than today's computer can accommodate is called an intractable problem, and these are the problems that the quantum computers are expected to solve.

The Potential of Quantum Computers

As soon as you enter the world of the atomic and subatomic particle, stuff starts behaving in unexpected ways. In fact, these particles are expected to exist in more than one state at a time. It is the ability that quantum computers take advantage of. Unlike the bits that are used by the conventional computers, quantum computers use bits that are known as qubits. Let us understand this with an example: imagine a sphere where a bit can lay at any of the two poles of the sphere. On the other hand, a qubit can lay at any point on the sphere. So, this means that a quantum computer using qubits can store an enormous amount of information and it requires less energy doing so as compared to a classical computer. Entering into this field of quantum computing where the laws of classical physics are no longer applicable, will enable us to create significantly faster microprocessors, then the ones that we use with conventional computers. This undoubtedly sounds interesting, but the challenge associated is that quantum computing is too incredibly complex. To understand the complexity, let’s first understand how quantum computers work.

How Quantum Computers Work?

The classical computers encode information in bits. Where each bit can take a value of either 1 or 0. These bits work as ON and OFF switch that is ultimately used by the computers for making decisions. On the other hand, quantum computers are based on qubits that are operated on two key principles of quantum physics: superposition and entanglement. Superposition states that each qubit can represent a 0 and a 1 at the same time. Whereas entanglement means that qubits in a superposition can be correlated with each other, i.e., the state of one can depend on the state of another. When using these two together, qubits start acting as more sophisticated switches. This enables the computer to function in ways that allow them to solve the complex problems that are unmanageable using today's computers. Let us go further and try to comprehend the scope and applications of a quantum computer.

What can a Quantum Computer do?

Quantum systems may simplify the complexity of molecular and chemical interactions. They may help to enable ultra efficient logistics and supply chains, such as optimizing the fleet operations for deliveries during the holiday season. They also make the features of machine learning more powerful.

Applications

Here are some of the areas that may be revolutionized with the help of quantum computing:
  • Medicines and Materials: Simplifying the chemical and molecular interactions that lead to the discovery of new drugs and materials.
  • Supply Chain and Logistics: Quantum computing helps to optimize the fleet operations for deliveries during the holiday season.
  • Financial Services: Finding new ways of making transactions secure, discover better financial models and identifying key global risk factors to beget better investments.
  • Artificial Intelligence: It helps to make the features and aspects of artificial intelligence more reliable and powerful when the data sets are very large.
Click here to read more about Artificial Intelligence.
Now that we understand what quantum computing is, let’s recapitulate the facts again.

Some facts about quantum computing

  • Quantum computing aims to take advantage of the concepts of wave-particle duality and uncertainty principle that subatomic particles exhibit.
  • Where a classical computer uses binary bits for performing calculations; a quantum computer uses qubits that exists in both of the states simultaneously, along with many other states in between.
  • The qubits are known for exhibiting the properties of quantum entanglement - it's a phenomenon that means pairs or group of particles cannot be measured or described independently for each other - that they are entangled and their state depends on that of other particles in the group.
  • Due to the factors that are still not fully understood despite the best efforts of Einstein, Schrodinger, and many others since it appears that particles linked in this way can transfer information between each other, even though theoretically, these could be at an unlimited distance apart.
  • The computer scientists that are working on quantum computers believe that in the future it could be possible harnessing these mechanisms and build computers that could be millions of times more efficient than anything that is available today.
  • The quantum computers require extremely cold temperatures as the subatomic particles should remain as close as possible to a stationary state to be measured.
  • Quantum Computing is often described as natural. This happens as we don't clearly understand them as the mechanisms underpinning the real world clearly operate at a subatomic level.
  • At a quantum level, science fiction appears to become reality. The particles can travel backward or forwards in time and teleport between two positions.

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