VIBRATION ANALYSIS OF HEAVY WEAPONS IN TRANSIT BY AIRCRAFT IN FRACTAL SPACE CONSIDERING LOCATION DEVIATION

Fractals Pub Date : 2024-01-18 DOI:10.1142/s0218348x2450018x

YONG-GANG Kang, Shuai-Jia Kou, SI-REN Song, YU-ZHEN Chang, AN-YANG Wang, YONG-GANG Chen

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Abstract

Air transportation constitutes a significant advancement in enhancing transportation efficiency. Nonetheless, when this modality is employed for the transit of large-scale armaments and equipment, the vibrational properties of these items within the aircraft’s cabin, coupled with potential deviations from their designated installation positions, emerge as critical factors that could compromise the safety of such transportation endeavors. To accommodate the unique environmental conditions of low-temperature and low-pressure prevalent in high-altitude air transportation, this model employs a fractal frequency formula for an expedited and accurate characterization of vibrational properties, while also providing a detailed analysis of the errors attributable to positional deviations in these vibration assessments. The findings of this research demonstrate that the computational accuracy achieved herein surpasses that of the variational iteration method (VIM) and the homotopy perturbation method (HPM). Moreover, the investigation into the damping effects of inertial forces within fractal dimensions unveils innovative prospects for optimizing nonlinear vibration systems under the challenging conditions of low-temperature and low-pressure environments.

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考虑位置偏差的飞机运输重型武器在分形空间中的振动分析

航空运输是提高运输效率的一大进步。然而，当采用这种方式运输大型武器装备时，这些物品在机舱内的振动特性，以及可能偏离其指定安装位置的情况，都成为危及此类运输安全的关键因素。为了适应高海拔航空运输中普遍存在的低温低压的独特环境条件，该模型采用了分形频率公式来快速准确地描述振动特性，同时还对这些振动评估中的位置偏差造成的误差进行了详细分析。研究结果表明，该模型的计算精度超过了变异迭代法（VIM）和同调扰动法（HPM）。此外，对分形维度内惯性力阻尼效应的研究为在低温低压环境的挑战条件下优化非线性振动系统开辟了创新前景。

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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Fractals

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