25 lines
1.6 KiB
Markdown
25 lines
1.6 KiB
Markdown
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- qubits should match the hardware
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- the and gate - you cannot do this reversibly on qubit but you can on a qutrit
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- qubit is emulated with a qutrit!
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- n qubit W state
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- the W state is necessary to perform the distributed computing task of leader lection in anonymous quantum network - it is usually the minimum spanning tree
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- efficiently, fault-tolerantly, deterministically
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----
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- strange, StrangeFX
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- no hardware acceleration
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- JIT compilation
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tornadovm.readthedocs.
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---
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##### Quantum Formalism Research Abstract
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**Abstract: **
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Please humor me if this is a stretch but I thought this something worth exploring from a more mathematical perspective and proof: As radio waves are currently the longest emitting electromagnetic frequencies, would they play a role in accounting for noise specifically in wind by formulating a way in which radio waves detecting noise via wind can communicate this rather naturally in a math formulation to quantum computing. There seems to be a lot of similarity between these two industries and rather than approaching it from a photonic or superconducting/circuit perspective, I wanted to take a moment to understand if this can be better formalized in an equation demonstrating the relationship between the earth’s wind, radio waves tested via ham amateur radio, and factoring these into error mitigation in quantum computing. Although many things may account for the noise that leaves quantum computers largely still unusable today, such as natural earth perturbations, I am still interested in primarily exploring atmospheric wind in a mathematical approach.
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