LOCC

From Wikipedia, the free encyclopedia

LOCC, or Local Operations and Classical Communication, is a method in quantum information theory where a local (product) operation is performed on part of the system, and where the result of that operation is "communicated" classically to another part where usually another local operation is performed. An example of this is distinguishing two Bell pairs, such as the following:

$|\psi_1\rangle = \frac{1}{\sqrt{2}}\left(|0\rangle_A\otimes|0\rangle_B + |1\rangle_A\otimes|1\rangle_B\right)$

$|\psi_2\rangle = \frac{1}{\sqrt{2}}\left(|0\rangle_A\otimes|1\rangle_B + |1\rangle_A\otimes|0\rangle_B\right)$

Let's say the two-qubit system is separated, where the first qubit is given to Alice and the second is given to Bob. Assume that Alice measures the first qubit, and obtains the result 0. We still don't know which Bell pair we were given. Alice sends the result to Bob over a classical channel, where Bob measures the second qubit, also obtaining 0. Bob now knows that since the joint measurement outcome is $|0\rangle_A\otimes|0\rangle_B$ , then the pair given was $|\psi_1\rangle$ .

These measurements contrasts with nonlocal or entangled measurements, where a single measurement is performed in $\mathbb{C}^{2n}$ instead of the product space $\mathbb{C}^2\otimes\mathbb{C}^n$ .

[edit] Entanglement manipulation

Nielson ^[1] has derived a general condition to determine whether one state my be transformed into another using only LOCC. Full details may be found in the paper referenced earlier, the results are sketched out here.

Consider two particles in a Hilbert space of dimension d with particle states $|\psi\rangle$ and $|\phi\rangle$ with Schmidt decompositions

$|\psi\rangle=\sum_i\sqrt{\lambda_i}|i_A\rangle\otimes|i_B\rangle$

$|\phi\rangle=\sum_i\sqrt{\lambda_i'}|i_A'\rangle\otimes|i_B'\rangle$

The $\sqrt{\lambda_i}$ 's are known as Schmidt coefficients. If they are ordered largest to smallest (i.e. with $λ 1 > λ d$ ) then $|\psi\rangle$ can only be transformed into $|\phi\rangle$ using only local operations if and only if for all $k$ in the range $1\leq k \leq d$

$\sum_{i=1}^k\lambda_i\leq\sum_{i=1}^k\lambda_i'$

In more concise notation:

$|\psi\rangle\rightarrow|\phi\rangle\textrm{ iff }\lambda \prec \lambda'$

This is a more restrictive condition that local operations cannot increase the degree of entanglement. It is quite possible neither $|\psi\rangle$ or $|\phi\rangle$ because neither set of Schmidt coefficients majorises the other. For large $d$ if all Schmidt coefficients are non-zero then the probability of one set of coefficients majorising the other becomes negligible. Therefore for large $d$ the probability of any arbitrary state being converted into another becomes negligible.

[edit] References

^ Phys. Rev. Lett. 83, 436 - 439 (1999)

[edit] Further reading

http://www.quantiki.org/wiki/index.php/LOCC_operations

v • d • e Quantum computing

General	Qubit • Quantum computer • Quantum information • Quantum programming • Quantum virtual machine • Timeline of quantum computing

Quantum communication	Quantum channel • Quantum cryptography • Quantum teleportation • LOCC • Entanglement distillation

Quantum algorithms	Universal quantum simulator • Deutsch-Jozsa algorithm • Grover's search • Shor's factorization • Simon's Algorithm • (BQP)

Quantum computing models	Quantum circuit (quantum gate) • One-way quantum computer (cluster state) • Adiabatic quantum computation

Decoherence prevention	Quantum error correction • Topological quantum computer

Physical implementations

Quantum optics	Linear optics QC • Cavity QED

Ultracold atoms	Trapped ion quantum computer • Optical lattice

Spin-based	Nuclear magnetic resonance (NMR) quantum computing • Kane QC • Loss-DiVincenzo (quantum dot) QC

Other	Superconducting quantum computing (Charge qubit • Flux qubit) • Nitrogen-vacancy center

Categories: Quantum information science

LOCC

From Wikipedia, the free encyclopedia

[edit] Entanglement manipulation

[edit] References

[edit] Further reading

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