Category:Entanglement Distribution Network stage: Difference between revisions
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The third network stage, entanglement distribution allows shared entanglement i.e. two nodes can be connected using [[Glossary#Entangled States|entanglement]]. It could be further used to share states between two nodes without physically transferring the qubits over quantum channels. Yet this feature cannot be completely put in use unless one can store quantum states which is only possible with quantum memory, not a technology accessible at this network stage. It includes all the prepare and measure network stage technologies along with sharing of entanglement between two nodes separated by some distance | The third network stage, entanglement distribution allows shared entanglement i.e. two nodes can be connected using [[Glossary#Entangled States|entanglement]]. It could be further used to share states between two nodes without physically transferring the qubits over quantum channels. Yet this feature cannot be completely put in use unless one can store quantum states which is only possible with quantum memory, not a technology accessible at this network stage. It includes all the prepare and measure network stage technologies along with sharing of entanglement between two nodes separated by some distance. [https://en.wikipedia.org/wiki/Postselection Post-selection] on detection events when measuring qubits is prohibited. | ||
largely untrusted.</br> | |||
==Applications and Features== | |||
The main advantage over the previous stages ([[:Category:Trusted Repeater Network Stage|Trusted Repeater]] and [[:Category:Prepare and Measure Network Stage|Prepare and Measure]]) is that this stage allows the realization of device independent protocols, in which the quantum devices are largely untrusted. It also allows generation of multipartite entangled states, followed by immediate measurements.</br> | |||
The network stage includes two types of end-to-end (shared between two nodes) entanglement, deterministic and heralded. Deterministic entanglement refers to the fact that the process succeeds with (near) unit probability while heralding is a slightly weaker form of deterministic entanglement distribution in which the successful generation of entanglement is signaled with an event that is independent of the (immediate) measurement of the entangled qubit. | The network stage includes two types of end-to-end (shared between two nodes) entanglement, deterministic and heralded. Deterministic entanglement refers to the fact that the process succeeds with (near) unit probability while heralding is a slightly weaker form of deterministic entanglement distribution in which the successful generation of entanglement is signaled with an event that is independent of the (immediate) measurement of the entangled qubit. | ||
Revision as of 01:02, 11 July 2019
The third network stage, entanglement distribution allows shared entanglement i.e. two nodes can be connected using entanglement. It could be further used to share states between two nodes without physically transferring the qubits over quantum channels. Yet this feature cannot be completely put in use unless one can store quantum states which is only possible with quantum memory, not a technology accessible at this network stage. It includes all the prepare and measure network stage technologies along with sharing of entanglement between two nodes separated by some distance. Post-selection on detection events when measuring qubits is prohibited.
Applications and Features
The main advantage over the previous stages (Trusted Repeater and Prepare and Measure) is that this stage allows the realization of device independent protocols, in which the quantum devices are largely untrusted. It also allows generation of multipartite entangled states, followed by immediate measurements.
The network stage includes two types of end-to-end (shared between two nodes) entanglement, deterministic and heralded. Deterministic entanglement refers to the fact that the process succeeds with (near) unit probability while heralding is a slightly weaker form of deterministic entanglement distribution in which the successful generation of entanglement is signaled with an event that is independent of the (immediate) measurement of the entangled qubit.
Relevant Parameters
Pages in category "Entanglement Distribution Network stage"
The following 5 pages are in this category, out of 5 total.