Exploring Entanglement: What is the Schmidt Rank?

In summary: But I think that if you have a measurement of entanglement, then the rank would be continuos and additive.In summary, the Schmidt rank is a measure of the entanglement between two quantum systems. It is continuos and additive, but for systems with local dimensional 2, it is not possible to have a measurement of entanglement with a Schmidt rank that is both continuos and additive.
  • #1
valesdn
42
1
Hi guys. I'm studying an article on the measurements of entanglement in a pure bipartite state.
I don't understand the definition of the Schmidt rank. It is equal to the rank of the reduced density matrix, isn't it?
Is the Schmidt rank continuous and/or additive? I have no found on the net any articles or information about this.
Could you help me?

Thanks in advance.
 
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  • #2
Are you referring to the schmidt decompositionhttps://en.wikipedia.org/wiki/Schmidt_decomposition)?

Maybe this blog post will be helpful?

Suppose you have a quantum system involving two parties, Alice and Bob. Alice has an ##n##-level quantum system, and Bob has an ##m##-level quantum system. The combined system can be described by ##n m## amplitudes. Arrange those amplitudes into a grid with ##n## rows and ##m## columns, where each row corresponds to one of Alice's system's levels and each column corresponds to one of Bob's system's levels. For example, if they both have a qubit then the grid would be laid out like:

Code:
              | Alice qubit OFF | Alice qubit ON
--------------+-----------------+----------------------
Bob qubit OFF | amplitude_00    | amplitude_01
Bob qubit ON  | amplitude_10    | amplitude_11

Which happens look a whole lot like a matrix:

##\begin{bmatrix} a_{00} & a_{01} \\ a_{10} & a_{11} \end{bmatrix}##

and if you treat it like a matrix, and perform a singular value decomposition to turn it into ##U \cdot S \cdot V##, then you'll find that Alice's operations affect ##U## and Bob's operations affect ##V## but neither of them can affect ##S##. Because ##S## is a pretty simple matrix, with nothing but real non-negative entries in descending order along its diagonal, it makes sense to think of the entries on that diagonal as a measure of the entanglement between Alice and Bob.

The terms on the diagonal of ##S## might be what you mean by "schmidt rank"?

Fully entangled systems have an equal value along the whole diagonal, making the system act a whole lot like a unitary matrix. Non-entangled systems have a single non-zero entry in the top left cell, and act like the tensor product of two vectors.
 
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  • #3
Where did you see the term, and how is it used?
 
  • #4
Thank you Strilanc for your explanation. I don't know if the terms on the diagonal are what I mean "Schmidt rank". I think so. I have just read that for all quantum system, the sum of all eigenvalues is essentially finite and the whole entangled system becomes finite dimensional. I don't know if it is useful to consider "not continuos" the Schmidt rank ( however it is possibile use continuous variables and define an infinite Schmidt rank, cit. Lewenstein). I should demonstrate that the rank is neither continuos nor additive.
Hi atyy. I read an article ( maybe lecture notes) where the Schmidt rank is defined as the number of terms in the Schmidt decomposition, and it is also equal to the dimension of the support of the reduced density matrix. That's all.
Could the Schmidt rank be a measurement of entanglement ( being neither continuos nor additive)? For systems with local dimensional 2, I think that it is not possible. I don't know how to explain it...
 

FAQ: Exploring Entanglement: What is the Schmidt Rank?

What is the definition of entanglement?

Entanglement is a phenomenon in quantum mechanics where two or more particles become connected in such a way that the state of one particle cannot be described independently of the other particles. This means that the particles are inextricably linked, even when they are separated by large distances.

What is the Schmidt rank?

The Schmidt rank is a measure of entanglement between two quantum systems. It is calculated by finding the number of non-zero eigenvalues of the reduced density matrix of one of the systems. The higher the Schmidt rank, the more entangled the systems are.

How is the Schmidt rank used in quantum information processing?

The Schmidt rank is often used to quantify the amount of entanglement in a quantum system. It can also be used to determine the optimal way to encode information in entangled states for tasks such as quantum communication and teleportation.

Can the Schmidt rank be used to compare entanglement between different systems?

Yes, the Schmidt rank can be used to compare entanglement between different systems. However, it is important to note that the Schmidt rank is not the only measure of entanglement and may not always provide a complete understanding of the entanglement between two systems.

How does the Schmidt rank relate to other measures of entanglement?

The Schmidt rank is closely related to other measures of entanglement such as the entanglement entropy and the concurrence. In some cases, the Schmidt rank can be used to calculate these other measures, but in general, different measures may be needed to fully describe the entanglement in a system.

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