On the Theory of Amplitude Distribution of Impulsive Random Noise

Furutsu, K.; Ishida, T.

doi:10.1063/1.1736206

Cited by 70 publications

(26 citation statements)

References 7 publications

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“…The result agrees with the characteristic function of the impulse noise derived in Ref. 15 by Furutsu and Ishida. In Ref.…”

Section: T] the Combined Distortion Noise Process R(t) Is Representesupporting

confidence: 92%

“…In Ref. 15, the analysis is based on the exponential distribution, and in Ref. 17, it is based on the Rayleigh distribution.…”

Section: T] the Combined Distortion Noise Process R(t) Is Representementioning

confidence: 99%

“…Using the characteristic function Φ R+G (λ) of the sum amplitude of the distortion due to clipping and the Gaussian noise, the cumulative probability P 0 (R > R 0 ) that the amplitude exceeds the given amplitude R 0 is given as follows [14,15] 24) is written as Thus, the probability density function [f(R)] of the distortion amplitude due to clipping, with additive Gaussian noise, is finally obtained as follows: …”

Section: Cumulative Amplitude Distribution and Probability Density Fumentioning

confidence: 99%

“…Consequently, there must be studies of the appropriate correction to the measured signal power, and a comparison of the corrected power and the theoretical value, for the case in which the signal has an amplitude distribution as impulse noise. This paper is based on the classical papers of Middleton [14] and Furutsu [15]. Considering the generation process of the distortion due to clipping, the statistical model is theoretically derived, and it is shown that its amplitude distribution follows Middletons class A model.…”

Section: Introductionmentioning

confidence: 99%

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Study of statistical model and power measurement results for distortions due to clipping in SCM optical transmission system

Maeda

Tsukamoto

Komaki

2002

Electron. Comm. Jpn. Pt. I

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In the SCM optical transmissions used in optical CATV, it has been pointed out that the distortion generated by clipping behaves in the same way as impulse noise. In this paper, it is assumed that the distortion due to clipping is generated following the Poisson distribution, with the same characteristics as the band‐limited noise, and it is demonstrated theoretically that the amplitude distribution follows Middleton's class A model. On the other hand, there have been many discussions of the theoretical value of the distortion power due to clipping. This study notes that the measurement of the noise power by the spectrum analyzer essentially contains a measurement error. Using the statistical model for the distortion amplitude derived in this paper, the measurement error is calculated for the case in which the amplitude distribution of the distortion due to clipping follows that of the impulse noise. The calculation result is compared to the measurement results and the amount of correction is theoretically derived for the very large error present in the distortion value indicated by the spectrum analyzer. In the SCM optical transmission used in optical CATV, the measured distortion is smaller than the actual value at the ordinary employed optical modulation index. The difference may sometimes reach 20 dB. When the measured value is corrected for the error by the method presented in this paper, the theoretical value of the distortion by clipping, as obtained from Saleh's expression, is almost entirely adequate. © 2002 Wiley Periodicals, Inc. Electron Comm Jpn Pt 1, 85(8): 13–22, 2002; Published online in Wiley InterScience (www.interscience.wiley.com). DOI 10.1002/ecja.1114

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“…The result agrees with the characteristic function of the impulse noise derived in Ref. 15 by Furutsu and Ishida. In Ref.…”

Section: T] the Combined Distortion Noise Process R(t) Is Representesupporting

confidence: 92%

“…In Ref. 15, the analysis is based on the exponential distribution, and in Ref. 17, it is based on the Rayleigh distribution.…”

Section: T] the Combined Distortion Noise Process R(t) Is Representementioning

confidence: 99%

Section: Cumulative Amplitude Distribution and Probability Density Fumentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Study of statistical model and power measurement results for distortions due to clipping in SCM optical transmission system

Maeda

Tsukamoto

Komaki

2002

Electron. Comm. Jpn. Pt. I

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show abstract

“…This is always satisfied for communication problems and is not nearly as strong an assumption as a Gaussian assumption. Almost all the available experimental data 4 :,-' have be,,n obtained in narrow-band conditions.…”

Section: A Introductionmentioning

confidence: 99%

Statistical Analysis of LF/VLF Communication Modems

Omura¹

1969

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Interference Modeling in Wireless Communications

Yang

Petropulu

2003

Wiley Encyclopedia of Telecommunications

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In wireless communication networks, signal reception is often corrupted by interference from other sources that share the same propagation medium. Knowledge of the statistics of interference is important in achieving optimum signal detection and estimation. We here discuss statistical‐physical models for modeling interference. The interesting feature of these models is that they are non‐Gaussian, and in certain cases are heavy‐tail distributed. The latter property introduces several challenges in the analysis of interference, since heavy‐tail processes lack second‐order statistics. A introduction on heavy‐tail processes is also provided.

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On the Theory of Amplitude Distribution of Impulsive Random Noise

Cited by 70 publications

References 7 publications

Study of statistical model and power measurement results for distortions due to clipping in SCM optical transmission system

Study of statistical model and power measurement results for distortions due to clipping in SCM optical transmission system

Statistical Analysis of LF/VLF Communication Modems

Interference Modeling in Wireless Communications

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