On the capacity of free-space optical intensity channels

Amos Lapidoth; Stefan M. Moser; Michèle A. Wigger

doi:10.1109/TIT.2009.2027522

On the capacity of free-space optical intensity channels

Amos Lapidoth, Stefan M. Moser, Michèle A. Wigger

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

Abstract

Upper and lower bounds are derived on the capacity of the free-space optical intensity channel. This channel has a nonnegative input (representing the transmitted optical intensity), which is corrupted by additive white Gaussian noise. To preserve the battery and for safety reasons, the input is constrained in both its average and its peak power. For a fixed ratio of the allowed average power to the allowed peak power, the difference between the upper and the lower bound tends to zero as the average power tends to infinity and their ratio tends to one as the average power tends to zero. When only an average power constraint is imposed on the input, the difference between the bounds tends to zero as the allowed average power tends to infinity, and their ratio tends to a constant as the allowed average power tends to zero.

Original language	English
Pages (from-to)	4449-4461
Number of pages	13
Journal	IEEE Transactions on Information Theory
Volume	55
Issue number	10
DOIs	https://doi.org/10.1109/TIT.2009.2027522
Publication status	Published - 8 Oct 2009
Externally published	Yes

Keywords

Channel capacity
Direct detection
Gaussian noise
Infrared communication
Optical communication
Pulse amplitude modulation (PAM)

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10.1109/TIT.2009.2027522

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title = "On the capacity of free-space optical intensity channels",

abstract = "Upper and lower bounds are derived on the capacity of the free-space optical intensity channel. This channel has a nonnegative input (representing the transmitted optical intensity), which is corrupted by additive white Gaussian noise. To preserve the battery and for safety reasons, the input is constrained in both its average and its peak power. For a fixed ratio of the allowed average power to the allowed peak power, the difference between the upper and the lower bound tends to zero as the average power tends to infinity and their ratio tends to one as the average power tends to zero. When only an average power constraint is imposed on the input, the difference between the bounds tends to zero as the allowed average power tends to infinity, and their ratio tends to a constant as the allowed average power tends to zero.",

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AU - Lapidoth, Amos

AU - Moser, Stefan M.

AU - Wigger, Michèle A.

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N2 - Upper and lower bounds are derived on the capacity of the free-space optical intensity channel. This channel has a nonnegative input (representing the transmitted optical intensity), which is corrupted by additive white Gaussian noise. To preserve the battery and for safety reasons, the input is constrained in both its average and its peak power. For a fixed ratio of the allowed average power to the allowed peak power, the difference between the upper and the lower bound tends to zero as the average power tends to infinity and their ratio tends to one as the average power tends to zero. When only an average power constraint is imposed on the input, the difference between the bounds tends to zero as the allowed average power tends to infinity, and their ratio tends to a constant as the allowed average power tends to zero.

AB - Upper and lower bounds are derived on the capacity of the free-space optical intensity channel. This channel has a nonnegative input (representing the transmitted optical intensity), which is corrupted by additive white Gaussian noise. To preserve the battery and for safety reasons, the input is constrained in both its average and its peak power. For a fixed ratio of the allowed average power to the allowed peak power, the difference between the upper and the lower bound tends to zero as the average power tends to infinity and their ratio tends to one as the average power tends to zero. When only an average power constraint is imposed on the input, the difference between the bounds tends to zero as the allowed average power tends to infinity, and their ratio tends to a constant as the allowed average power tends to zero.

KW - Channel capacity

KW - Direct detection

KW - Gaussian noise

KW - Infrared communication

KW - Optical communication

KW - Pulse amplitude modulation (PAM)

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DO - 10.1109/TIT.2009.2027522

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SP - 4449

EP - 4461

JO - IEEE Transactions on Information Theory

JF - IEEE Transactions on Information Theory

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On the capacity of free-space optical intensity channels

Abstract

Keywords

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