Physics Asked by Jack Rock on February 16, 2021
Question is: How is the set of states $Q$ logically replaced by a Hilbert space if a classical Turing machine is described by a 7-tuple $M=langle Q,Gamma, b,Sigma, delta, q_ {0},Frangle$?
I read here that the set of states Q is replaced by a Hilbert space.
But I want to understand how Hilbert Space is represented in quantum electronics, using Quantum gate circuits
I don’t know if this is a physical question but I think that is important to understand what way we need to use if we want represent with (quantum) logical circuits this ‘Hilbert space’.
I try to read also here but is not very clear how a Hilbert space is manipulated as a quantum logical circuit
https://en.wikipedia.org/wiki/Quantum_finite_automaton
But I want to understand how Hilbert Space is represented in quantum electronics, using Quantum gate circuits
Here is a picture of a quantum gate circuit. Those input states --- $ |psirangle , |0rangle$ --- are elements of the Hilbert space that the computation takes place in.
How is the set of states Q logically replaced by a Hilbert space
This is harder to answer completely in short form. All I can say is that there is some function which takes as an input an element of $Q$ and maps it to an element of Hilbert space. For example, a trivial map would take any element of $Q$ and map it onto $|0rangle$. That's not very useful, but it's the kind of thing you're asking about. More complicated maps exist.
Correct answer by psitae on February 16, 2021
Get help from others!
Recent Questions
Recent Answers
© 2024 TransWikia.com. All rights reserved. Sites we Love: PCI Database, UKBizDB, Menu Kuliner, Sharing RPP