Revision as of 22:19, 21 May 2026

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Quantum Boson sampling is a planned ScholarlyWiki page in the Quantum Collection about boson sampling and photonic quantum computation.

Overview

Placeholder: describe boson sampling as a restricted photonic model in which identical photons pass through a linear optical network and produce output samples.

@@ Line 1: / Line 1: @@
-{{Short description|Maximally entangled two-qubit quantum state}}
+{{Short description|Photonic sampling model for quantum advantage studies}}
 {{ScholarlyWiki page top
 |backlink={{Quantum book backlink|Quantum information and computing}}
-{{Quantum article nav|previous=Physics:Quantum Entanglement|previous label=Entanglement|next=Physics:Quantum Gates and circuits|next label=Gates and circuits}}
+{{Quantum article nav|previous=Physics:Quantum Noisy Qubits|previous label=Noisy Qubits|next=Physics:Quantum random access code|next label=Random access code}}
-|image=[[File:Quantum_Bell_state_educational_yellow.png|430px|Bell states as correlated two-qubit entangled states used in quantum information.]]
+|image=[[File:Quantum_Boson_sampling_educational_yellow.png|430px|Boson sampling with photons passing through a multiport interferometer and sampled at detectors.]]
-|text='''Quantum Bell state''' is a planned ScholarlyWiki page in the Quantum Collection about Bell states and two-qubit entanglement.
+|text='''Quantum Boson sampling''' is a planned ScholarlyWiki page in the Quantum Collection about boson sampling and photonic quantum computation.
 }}
 == Overview ==
-Placeholder: introduce Bell states as maximally entangled two-qubit states and explain why they are central in quantum information.
+Placeholder: describe boson sampling as a restricted photonic model in which identical photons pass through a linear optical network and produce output samples.
 == Key ideas ==
-Placeholder: cover entanglement, two-qubit correlations, Bell basis, quantum teleportation, superdense coding.
+Placeholder: cover indistinguishable photons, linear optics, interferometers, output distributions, quantum advantage.
-== Bell basis ==
+== Linear optical network ==
 Placeholder: develop this section with definitions, examples, formulas, and links to related Quantum Collection pages.
-== Correlations ==
+== Sampling task ==
 Placeholder: develop this section with definitions, examples, formulas, and links to related Quantum Collection pages.
-== Preparation in circuits ==
+== Computational significance ==
 Placeholder: develop this section with definitions, examples, formulas, and links to related Quantum Collection pages.
-== Uses in protocols ==
+== Experimental considerations ==
 Placeholder: develop this section with definitions, examples, formulas, and links to related Quantum Collection pages.
@@ Line 34: / Line 34: @@
 {{Author|Harold Foppele}}
-{{Sourceattribution|Physics:Quantum Bell state|1}}
+{{Sourceattribution|Physics:Quantum Boson sampling|1}}

Script: Difference between revisions

Revision as of 22:19, 21 May 2026

Overview

Key ideas

Linear optical network

Sampling task

Computational significance

Experimental considerations

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