VIDEO Quantum Computing 2017 Update

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Quantum Computing 2017 Update In the fascinating realm of technology, quantum computing emerges as a revolutionary force, poised to redefine data processing. This update, stemming from the enlightening YouTube video titled "Quantum Computing 2017 Update," offers a comprehensive overview of quantum computing developments as of 2017, while also hinting at future implications.

Key Insights and Concepts​

Foundation of Quantum Computing: Unlike classical computers that rely on bits (binary digits) represented by the absence or presence of an electrical charge, quantum computers utilize qubits. These qubits can exist in multiple states simultaneously due to the principles of superposition, allowing for vastly superior data processing capabilities. For example, while a classical bit is either a 0 or a 1, a qubit can be both at the same time, vastly expanding the potential computation pathways. Quantum Mechanics in Action: The video highlights how qubits can also become entangled, a phenomenon where the state of one qubit is dependent on another, regardless of the distance separating them. This entanglement allows quantum computers to solve complex problems more efficiently than their classical counterparts, which may include tasks such as molecular modelling, logistical problem-solving, or advanced deep learning applications.

Major Players in Quantum Computing​

• IBM: With over 35 years of research under its belt, IBM took significant steps in quantum computing in 2016 by releasing a five-qubit quantum computer for public use. By March 2017, IBM Q was established, aiming to commercialize quantum computing to be accessed via the cloud, indicating a shift towards practical applications and accessibility.
• D-Wave Systems: Known for developing the first commercially sold quantum computer, D-Wave has been at the forefront of quantum technology since 2007. Their approach, however, has been controversial due to its reliance on quantum annealing—a method some experts criticize as less flexible than IBM's gate-based approach.
• Google and Microsoft: Google is concurrently developing its quantum technology, with plans to test a 20-qubit machine and aspirations for a 49-qubit system. Meanwhile, Microsoft’s Station Q initiative focuses on various quantum research projects, particularly in topological quantum computing.
• Intel and Alibaba: Intel has ventured into creating quantum computers using traditional silicon technology, while Alibaba, in collaboration with the Chinese Academy of Sciences, aims at pioneering quantum applications through dedicated research.

  Future Implications​

  The rising capability of quantum computers is anticipated to complement traditional computers. In the next decade, we could see quantum systems powering new artificial intelligence applications and sophisticated data services. As the video suggests, it's plausible we may interact with digital assistants that leverage quantum computing technology, fundamentally transforming our engagement with technology.

  Conclusion​

  The video serves as more than just an informative update; it paints a picture of an impending technological shift that's already underway. The potential of quantum computing to revolutionize various sectors from cybersecurity to artificial intelligence is immense, and the developments showcased offer a glimpse into a future where conventional computing methods may be profoundly enriched by quantum technologies. If this topic intrigues you, feel free to share your thoughts or experiences with quantum computing. Have you explored quantum programming? What are your predictions for its future impact? Let's discuss!​

  For further insights, you may want to check out other community threads discussing advancements in artificial intelligence or cloud computing solutions.