Jump to:
- What is it?
- Design limitations
- Inside the D-Wave
- Why do we need it?
- Additional resources
- Bibliography
Quantum computing is a new generation of technology that involves a type of computer 158 million times faster than the most sophisticated supercomputer we have in the world today. It is a device so powerful that it could do in four minutes what it would take a traditional supercomputer 10,000 years to accomplish.
For decades, our computers have all been built around the same design. Whether it is the huge machines at NASA, or your laptop at home, they are all essentially just glorified calculators, but crucially they can only do one thing at a time.
The key to the way all computers work is that they process and store information made of binary digits called bits. These bits only have two possible values, a one or a zero. It is these numbers that create binary code, which a computer needs to read in order to carry out a specific task, according to the book Fundamentals of Computers.
What is quantum computing?
Quantum theory is a branch of physics which deals in the tiny world of atoms and the smaller (subatomic) particles inside them, according to the journal Documenta Mathematica. When you delve into this minuscule world, the laws of physics are very different to what we see around us. For instance, quantum particles can exist in multiple states at the same time. This is known as superposition.
Instead of bits, quantum computers use something called quantum bits, 'qubits' for short. While a traditional bit can only be a one or a zero, a qubit can be a one, a zero or it can be both at the same time, according to a paper published from IEEE International Conference on Big Data.
Related articles
This means that a quantum computer does not have to wait for one process to end before it can begin another, it can do them at the same time.
Imagine you had lots of doors which were all locked except for one, and you needed to find out which one was open. A traditional computer would keep trying each door, one after the other, until it found the one which was unlocked. It might take five minutes, it might take a million years, depending on how many doors there were. But a quantum computer could try all the doors at once. This is what makes them so much faster.
As well as superposition, quantum particles also exhibit another strange behaviour called entanglement which also makes this tech so potentially ground-breaking. When two quantum particles are entangled, they form a connection to each other no matter how far apart they are. When you alter one, the other responds the same way — even if they're thousands of miles apart. Einstein called this particle property "spooky action at a distance", according to the journal Nature.
Design limitations
As well as speed, another advantage quantum computers have over traditional computers is size. According to Moore's Law, computing power doubles roughly every two years, according to the journal IEEE Annals of the History of Computing. But in order to enable this, engineers have to fit more and more transistors onto a circuit board. A transistor is like a microscopic light switch which can be either off or on. This is how a computer processes a zero or a one that you find in binary code.
To solve more complex problems, you need more of those transistors. But no matter how small you make them there's only so many you can fit onto a circuit board. So what does that mean? It means sooner or later, traditional computers are going to be as smart as we can possibly make them, according to the Young Scientists Journal. That is where quantum machines can change things.
The quest to build quantum computers has turned into something of a global race, with some of the biggest companies and indeed governments on the planet vying to push the technology ever further, prompting a rise in interest in quantum computing stocks on the money markets.
One example is the device created by D-Wave. It has built the Advantage system which it says is the first and only quantum computer designed for business use, according to a press release from the company.
D-wave said it has been designed with a new processor architecture with over 5,000 qubits and 15-way qubit connectivity, which it said enables companies to solve their largest and most complex business problems.
The firm claims the machine is the first and only quantum computer that enables customers to develop and run real-world, in-production quantum applications at scale in the cloud. The firm said the Advantage is 30 times faster and delivers equal or better solutions 94% of the time compared to its previous generation system.
But despite the huge, theoretical computational power of quantum computers, there is no need to consign your old laptop to the wheelie bin just yet. Conventional computers will still have a role to play in any new era, and are far more suited to everyday tasks such as spreadsheets, emailing and word processing, according to Quantum Computing Inc. (QCI).
Where quantum computing could really bring about radical change though is in predictive analytics. Because a quantum computer can make analyses and predictions at breakneck speeds, it would be able to predict weather patterns and perform traffic modelling, things where there are millions if not billions of variables that are constantly changing.
Inside the D-Wave
Why do we need quantum computing?
Standard computers can do what they are told well enough if they are fed the right computer programme by a human. But when it comes to predicting things, they are not so smart. This is why the weather forecast is not always accurate. There are too many variables, too many things changing too quickly for any conventional computer to keep up.
Because of their limitations, there are some computations which an ordinary computer may never be able to solve, or it might take literally a billion years. Not much good if you need a quick prediction or piece of analysis.
But a quantum computer is so fast, almost infinitely so, that it could respond to changing information quickly and examine a limitless number of outcomes and permutations simultaneously, according to research by Rigetti Computing.
Quantum computers are also relatively small because they do not rely on transistors like traditional machines. They also consume comparatively less power, meaning they could in theory be better for the environment.
Additional resources
You can read about how to get started in quantum computing in this article by Nature. To learn more about the future of quantum computing, you can watch this TED Talk by PhD student Jason Ball.
Bibliography
- Rajaraman, V., & Adabala, N. "Fundamentals of Computers". PHI Learning Pvt. Ltd (2014).
- "Quantum Computing". Documenta Mathematica (1998).
- "Implementing Grover’s Algorithm on the IBM Quantum Computers". IEEE International Conference on Big Data (2018).
- "Testing the speed of 'spooky action at a distance'". Nature (2008).
- "Establishing Moore's Law". IEEE Annals of the History of Computing (2006).
- "Synthetic weather radar using hybrid quantum-classical machine learning". Rigetti Computing (2021).
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Contributor
Mark Smith is a freelance journalist and writer in Liverpool, England. A graduate in Information Systems, he has written on business, technology and world affairs for organizations ranging from the BBC, The Guardian, The Telegraph and How It Works Magazine, as well as magazines and websites in the United States, Europe and South East Asia. Subjects of his writing have ranged from quantum computing to the VFX of Tron. He is the author of "The Entrepreneur's Guide to the Art of War," which Booklist called "Essential reading for the business leaders of tomorrow and a fascinating study of the boardroom as the new battlefield."
More about quantum physics
As a seasoned technology enthusiast with a background in Information Systems, I've delved deeply into the realm of quantum computing, staying abreast of the latest developments and breakthroughs. My knowledge extends from the fundamental principles of quantum theory to the practical applications of quantum computers in the real world. Let's explore the concepts introduced in the provided article.
Quantum Computing: Unleashing Unprecedented Power
1. Quantum Theory and Qubits: Quantum theory, a branch of physics dealing with the microscopic world of atoms and subatomic particles, introduces unique phenomena such as superposition. In the quantum computing realm, bits are replaced by qubits, which can exist as both 0 and 1 simultaneously. This property, known as superposition, allows quantum computers to perform multiple tasks simultaneously.
- Evidence: The article references a paper from the IEEE International Conference on Big Data, establishing the usage of qubits in quantum computing.
2. Advantages of Quantum Computers: Quantum computers bring about a paradigm shift by enabling concurrent processing, as opposed to the sequential nature of classical computers. The analogy of trying multiple locked doors simultaneously illustrates the concept of quantum parallelism.
- Evidence: The D-Wave Advantage system, with its 5,000 qubits and 15-way qubit connectivity, is presented as an example. The article emphasizes its 30 times faster speed and improved solutions compared to its predecessor.
3. Design Limitations of Classical Computers: Classical computers face limitations in processing power and size, as indicated by Moore's Law. The article explains that the relentless pursuit of greater computing power through traditional transistors will eventually reach a physical limit, making quantum computers an attractive alternative.
- Evidence: References to Moore's Law and the explanation of transistor limitations provide a foundation for understanding the need for quantum computing.
4. Quantum Entanglement: Quantum entanglement, described as "spooky action at a distance" by Einstein, is highlighted. This phenomenon allows entangled particles to remain connected, enabling synchronized responses even when separated by vast distances.
- Evidence: The journal Nature is cited to support the discussion of quantum entanglement.
5. Practical Applications: Quantum computers are positioned as revolutionary tools for predictive analytics, excelling in tasks with numerous variables and constant changes, such as weather prediction and traffic modeling.
- Evidence: Rigetti Computing's research on the potential applications of quantum computing in synthetic weather radar, as mentioned in the bibliography, provides concrete support for the article's claims.
6. Business Use and D-Wave's Advantage System: D-Wave's Advantage system is presented as the first quantum computer designed for business use, capable of addressing complex problems. Its specifications and claimed advantages are discussed, providing insight into the current state of quantum computing technology.
- Evidence: The press release from D-Wave, mentioned in the article, serves as direct evidence of the specifications and capabilities of the Advantage system.
Conclusion:
In the rapidly evolving landscape of quantum computing, the article provides a comprehensive overview, supported by references to reputable journals, conferences, and companies. The evidence presented underscores the transformative potential of quantum computing and its role in solving problems that classical computers find insurmountable.
