در این قسمت از QuantumCasts ، دانیل سانک درباره تفاوت بین اطلاعات کلاسیک و کوانتومی در سطح بدنی و چگونگی استفاده از اطلاعات کوانتومی در وسایل ابررسانا بحث می کند. خواهید آموخت که چه چیزی یک موتور مکانیکی کوانتومی و برخی از چالش هایی را که محققان در حفظ اطلاعات کوانتومی با آن روبرو هستند ، انجام می دهد. برای قسمت های آینده با ما در ارتباط باشید و با کلیک روی اینجا در کانال ما مشترک شوید
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but can it run Crysis? :))
could we build a quantum computer in space then use power of the sun to power the quantum computer then use the super cold temps of space to cool the quantum computer than try to Entangled the quantum computer
Why can't we make a quantum cube which doesn't interact with the other particles? Instead of a flat chip, we can make a closed cube inside which qubits are built.
Amazing video! thank you! well explained. I think its great to learn more about how errors get produced! We should have a think tank for the subject. Qubit fab is the future. I can't wait to hear more from the team regarding its progress. Also what classes / degrees are required to get into this type of work?
<3 the hair
1 What kind of capacitor? Would a variable capacitor that a separate computer hooked up to with sensors help with noise and calibration?
1 Also, is a cross the most geometrically efficient shape? Could it be adapted into an equilateral triangle?
3 What are the two devices at the top and right of the cross? Do those combine as the capacitor?
Very informative…..!!!!!.
Can a quantum computer predict my thoughts before I think them, eventually?
Does anyone know if tensorflow 1.12, CUDA 10 and CUDNN 7.4 are all compatible?
Put the components in a vacuum and raise the temperature equal to the one in space you should get almost 0 errors
How is the software written to perform operations? I guess the system language would be more challenging than a classical computer
Cool vid
Thanks for the video Daniel,
If I got it well, you are proposing a new chip (8 times colder than space) simulating the operations of Cryostat. The superposition is ensured by the Superconductivity at steady rate, but we could have some errors.
My questions: Does this chip also manipulate true electrons inside for the superposition states (as the Cryostat), or States are hardcoded in the simulation? Is it possible to use this chip to create small quantum computers (like PCs) and make them available for the public?
Correct me if I made a mistake, please.
I don't understand why does it matter if information is leaked? Can't we avoid errors by simply not receiving the information? after all information exchange happens in a system.
nvidia and intel dead it seems
This is my favorite vídeo series right now. Please more episodes 🙂
Cool video, thanks! Would be great to know more about the current challenges you guys are facing, maybe in a follow-up? Also would be really interesting to see a lab tour type of video. You mentioned improving the superconducting material purity – is that a part of the research you do? So it's not just software / hardware development, it's also material science and physics? Sounds very interesting.
Great video
very compelling intro
I could not understand all the stuff because I do not understand physics well, but I am interested now a lot, thanks Dan
Not easy concepts to explain but good video
Good job @daniel sank
Nice work Dan!
Classical qubit already meet its peak?! #Superconducting qubits then we hit a paradox #Quantum qubits, using it against it self
I'm still confused how logical operations are performed and the results observed. A good amount of time of this video was spent focusing on explaining the protection the qubit circuitry from any interference, even so much as a photon, but then it was said that logic operations are sent to the qubits for processing, and no explanation was given.
(1) How are the logic operations sent to the qubits for processing without changing the qubits into an unknown state?
(2) And how are the results observed without altering the answer? Observation involves interaction with the qubit, even if it is so much as a photon or a very sensitive electromagnetic field sensor that responds by sending out a signal (which itself generates a new electromagnetic field), and if the qubits are supposed to be protected from such things, how are answers observed?