Nonlinear propagation of shaped supersonic signatures through turbulence

Proc. Meet. Acoust. Pub Date : 2018-10-08 DOI:10.1121/2.0000872

Trevor A. Stout, V. Sparrow

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引用次数: 4

Abstract

The amplitude and loudness of conventional N-wave sonic booms vary randomly after propagating through atmospheric turbulence towards the ground. Recent studies have shown that the turbulence effect depends on the amplitude of incoming N-wave. The next generation of supersonic aircraft are designed to produce shaped booms, which are generally lower in amplitude than N-waves and contain shocks with much longer rise times. In this paper, the effect of nonlinearity on shaped sonic booms propagating through turbulence is compared with that for N-waves. Results suggest that nonlinearity may have a negligible impact on loudness variations for shaped signatures, while the impact for N-waves can be significant. Propagation is modeled by solving an augmented KZK propagation equation including the effects of diffraction, thermoviscous absorption, relaxation, nonlinearity, and wind fluctuations.The amplitude and loudness of conventional N-wave sonic booms vary randomly after propagating through atmospheric turbulence towards the ground. Recent studies have shown that the turbulence effect depends on the amplitude of incoming N-wave. The next generation of supersonic aircraft are designed to produce shaped booms, which are generally lower in amplitude than N-waves and contain shocks with much longer rise times. In this paper, the effect of nonlinearity on shaped sonic booms propagating through turbulence is compared with that for N-waves. Results suggest that nonlinearity may have a negligible impact on loudness variations for shaped signatures, while the impact for N-waves can be significant. Propagation is modeled by solving an augmented KZK propagation equation including the effects of diffraction, thermoviscous absorption, relaxation, nonlinearity, and wind fluctuations.

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异形超音速信号在湍流中的非线性传播

传统的n波音爆在通过大气湍流向地面传播后，其振幅和响度随机变化。最近的研究表明，湍流效应取决于入射n波的振幅。下一代超音速飞机的设计目的是产生形状的爆轰，这种爆轰的振幅通常低于n波，并且包含上升时间更长的冲击。本文将非线性对异形音爆在湍流中传播的影响与对n波传播的影响进行了比较。结果表明，非线性对形状特征响度变化的影响可以忽略不计，而对n波的影响可能是显著的。通过求解扩展的KZK传播方程，包括衍射、热粘性吸收、弛豫、非线性和风波动的影响，建立了传播模型。传统的n波音爆在通过大气湍流向地面传播后，其振幅和响度随机变化。最近的研究表明，湍流效应取决于入射n波的振幅。下一代超音速飞机的设计目的是产生形状的爆轰，这种爆轰的振幅通常低于n波，并且包含上升时间更长的冲击。本文将非线性对异形音爆在湍流中传播的影响与对n波传播的影响进行了比较。结果表明，非线性对形状特征响度变化的影响可以忽略不计，而对n波的影响可能是显著的。通过求解扩展的KZK传播方程，包括衍射、热粘性吸收、弛豫、非线性和风波动的影响，建立了传播模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proc. Meet. Acoust.

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