Quantum-limited discrimination of laser light and thermal light

Jonathan L. Habif; Arunkumar Jagannathan; Samuel Gartenstein; Phoebe Amory; Saikat Guha

doi:10.1364/OE.417989

Quantum-limited discrimination of laser light and thermal light

Jonathan L. Habif, Arunkumar Jagannathan, Samuel Gartenstein, Phoebe Amory, Saikat Guha

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Understanding the fundamental sensitivity limit of an optical sensor requires a full quantum mechanical description of the sensing task. In this work, we calculate the fundamental (quantum) limit for discriminating between pure laser light and thermal noise in a photon-starved regime. The Helstrom bound for discrimination error probability for single mode measurement is computed along with error probability bounds for direct detection, coherent homodyne detection and the Kennedy receiver. A generalized Kennedy (GK) receiver is shown to closely approach the Helstrom limit. We present an experimental demonstration of this sensing task and demonstrate a 15.4 dB improvement in discrimination sensitivity over direct detection using a GK receiver and an improvement of 19.4% in error probability over coherent detection.

Original language	English (US)
Pages (from-to)	7418-7427
Number of pages	10
Journal	Optics Express
Volume	29
Issue number	5
DOIs	https://doi.org/10.1364/OE.417989
State	Published - Mar 1 2021

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics

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10.1364/OE.417989

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title = "Quantum-limited discrimination of laser light and thermal light",

abstract = "Understanding the fundamental sensitivity limit of an optical sensor requires a full quantum mechanical description of the sensing task. In this work, we calculate the fundamental (quantum) limit for discriminating between pure laser light and thermal noise in a photon-starved regime. The Helstrom bound for discrimination error probability for single mode measurement is computed along with error probability bounds for direct detection, coherent homodyne detection and the Kennedy receiver. A generalized Kennedy (GK) receiver is shown to closely approach the Helstrom limit. We present an experimental demonstration of this sensing task and demonstrate a 15.4 dB improvement in discrimination sensitivity over direct detection using a GK receiver and an improvement of 19.4% in error probability over coherent detection.",

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AU - Habif, Jonathan L.

AU - Jagannathan, Arunkumar

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AU - Amory, Phoebe

AU - Guha, Saikat

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AB - Understanding the fundamental sensitivity limit of an optical sensor requires a full quantum mechanical description of the sensing task. In this work, we calculate the fundamental (quantum) limit for discriminating between pure laser light and thermal noise in a photon-starved regime. The Helstrom bound for discrimination error probability for single mode measurement is computed along with error probability bounds for direct detection, coherent homodyne detection and the Kennedy receiver. A generalized Kennedy (GK) receiver is shown to closely approach the Helstrom limit. We present an experimental demonstration of this sensing task and demonstrate a 15.4 dB improvement in discrimination sensitivity over direct detection using a GK receiver and an improvement of 19.4% in error probability over coherent detection.

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Quantum-limited discrimination of laser light and thermal light

Abstract

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