Classical Computers Beating Quantum Computers: A Big Change in Computers?

Hi there everyone it's the business guy back again. I was going through an article online and it really interested me.

It was about Quantum computers.

Source

• Here's the Link to the website and here's my honest opinion about it friends

Blog Source

Some of the things that normal, everyday computers do might be better than quantum computers. Quantum computers are supposed to be super fast and clever, but they get stuck in some places.

Normal, regular computer is not as complicated as this.

When it comes to regular computers, they use 0s and 1s while quantum ones depend on qubits which can sometimes take the form of both 0 and 1 at the same time. This is the reason why these new quantum computers are hailed and yet their main challenge lies in sustaining them.

There have been a few scientists who think that ordinary machines could behave like quantum ones if they did not have those problems.

They simply came up with a special program which discards all unnecessary details from data as we usually do when we want to save space by reducing size of a picture file.

This system allowed them to overcome problems that had formerly seemed insurmountable for quantum computing.

Regular computers can be just as good as quantum ones in certain situations (Dr Dries Sels, New York University). In other words, Joseph Tindall from Flatiron Institute says it’s like making pictures smaller without losing much quality.

Although usual machines have not yet switched to such kind of processing different types of data, this future step can make them stronger and redefine our traditional notions concerning computational superiority

Regular computers still have some tricks up their sleeves to compete with quantum computers. While quantum computers sound amazing, regular computers might still have some tricks up their sleeves to compete with them.

It's all about finding new ways to make computers smarter and faster, no matter if they're classical or quantum. That's all for this blog, thanks for the time.