@NieldeBeaudrap: to me normalization seems to causes creation of energy. For example, if a world is split into two with equal probability. Without normalization, the energy will split equally into the two worlds. However, in our own world, we observe the conservation law of energy, which necessitate normalization. Of course, all the argument here is trying to find something consistent with my intuition, which is likely wrong in the quantum world. — czwang 9 mins ago

thank you very much it works now. Can you please clarify my doubts on the implementation of the circuit for Reflecion over the mean and the final parts of Grover's Algorithm implementation — varun palakodeti 1 min ago

Yes, I'm aware of this question: quantumcomputing.stackexchange.com/questions/5444/… — newbie 11 mins ago

If you clarify what your doubts are... If you're converting marking oracle to phase oracle, or use the same technique for implementing reflections, then yes, you use auxiliary qubit as target qubit. You can see examples in the same kata. — Mariia Mykhailova 5 mins ago

Fundamentally, work out the classical circuit and make it reversible via standard methods (there are several questions addressing this on the site). Also, see quantumcomputing.stackexchange.com/q/6842/1837 — DaftWullie 11 mins ago

Internal to each world, you have unit normalisation --- because you've already conditioned upon being in that world. Without such conditioning, the normalisation of each of the branches is less than 1. That's basically the only additional idea you need, I think. — Niel de Beaudrap 24 mins ago

I don't think that quantum computers are significantly advanced yet as to be able to perform calculations such as the md5 hash, especially as this is not a problem that can inherently be improved using quantum computer. I would suggest coming up with your own hash and implementing that as a starting point. — met927 20 mins ago

The first distance is the length of the geodesic (corresponding to the Fubiny-Study metric) on the complex projective space $CP^{n-1}$ connecting the two rays (defined by the two vectors). It can be computed, for instance, by solving the Hamilton-Jacobi equation. — David Bar Moshe 20 mins ago

I did not understand the part "use the same technique for implementing reflections" can you please clarify mam. — varun palakodeti 5 mins ago

when talking about "quantum memories" people usually refer to the problem of storing quantum states for prolonged amounts of times (whatever that means in a given setup). This doesn't have much to do the question at hand, which is about how classical data can be loaded/encoded as a quantum state in the first place. — glS 12 mins ago

"Overall, data can be stored classically and access via hybrid algorithms" I mean, every single "quantum algorithm" is a "hybrid algorithm", even though we often only discuss explicitly the quantum part of it. You need classical inputs and outputs to talk meaningfully of an algorithm doing something. This doesn't have much to do with the question of how QCs can access classical datasets (the qRAM part of the answer does though) — glS 14 mins ago

@gIS: You are right that input and output are classical for all algorithms. But when we will have qRAMs we will simply copy classical data there, process them on quantum computer without any interaction with classical computer and then we will read the output. Input and output are the only classical part and all processing is done on quantum computer. But now, to process big amount of data, quantum computer has to communicate with classical storage more often because the quantum computer does not have a memory, only few qubits in qunatum processor itself. — Martin Vesely 23 mins ago

"Conditional phase shift" step of Grover's search can be implemented in a similar way to the oracle application using an auxiliary qubit with a marked state 0..0. That is shown in ConditionalPhaseFlip_Reference operation in the same kata. — Mariia Mykhailova 22 mins ago