Grover's search algorithm is not really suited for database search. The examples that use hardcoded values that we search for don't do it justice for the precise reason you pointed out. Tag "grovers-algorithm" on this site has a lot of great questions and answers on this, starting with quantumcomputing.stackexchange.com/questions/6325/… — Mariia Mykhailova 23 mins ago

It probably doesn’t make sense to build a quantum computer in your house if the purpose of the exercise is to execute quantum algorithms. But the purpose may be learning about quantum computer hardware, or research into its construction, for which purposes a cloud-based solution is of course useless. — Mike Scott 2 mins ago

I don't quite understand what you mean by 1-site reduced density matrices. Could you send me a reference on that? is that I've only been studying this subject for a short time — Dani 11 mins ago

Thank you for this answer. I thought Grover's algorithm was specifically designed to search a database. I think I was misinformed (arxiv.org/abs/quant-ph/9605043). However, even on the Wiki page it says, "Although the purpose of Grover's algorithm is usually described as "searching a database", it may be more accurate to describe it as "inverting a function". In fact since the oracle for an unstructured database requires at least linear complexity, the algorithm cannot be used for actual databases." Again, thank you for your help and patience. — James Arneberg 13 mins ago

Given that you need an operating temperature of around -273C, it doesn't seem plausible (at least to me) that being in a cold country will make any kind of significant difference. — JBentley 17 mins ago

We will keep track of the whole system states via the density matrix, allowing for superpositions of states, applying the gates as tensor products, which will effectively give us one unitary acting on the initial density matrix, from this the probability of measuring the final product states, using a measure M, can be read off as the simulated outputs. — Sam Palmer 10 mins ago

You're welcome :-) Feel free to accept the answer ;-) — Mariia Mykhailova 11 mins ago

You might want to list the results you see as different between them. I don't expect a lot of people are going to be closely familiar with the implementations of both methods, so the more details you provide about your doubts, the higher is your chance of getting a good answer. — Mariia Mykhailova 11 mins ago

As far as I understand from the paper, eq. (13) gives $U_l$ as a product of two qubit unitaries, independently of $l(z)$. Then the authors presents two cases, subset parity and subset majority, and derive their specific $U_l$. Thus I guess your classification problem will need its own specialization of eq. (13). If you get an acceptable accuracy with the subset parity $U_l$, it may be a coincidence. Or maybe it is not, it depends on how your classification problem relates to subset parity. — Michele Amoretti 6 mins ago

@Dani Any introductory quantum information textbook will do. — Norbert Schuch 14 mins ago

Could anyone please provide some explanations regarding Qiskit initialize? The new file does not seem to contain this info :( — mavzolej 11 mins ago