This paper details the analysis of the relationship between the near-field pressure fluctuations of an unforced, subsonic free jet (0.4 ≤ M ≤ 0.6) and its low-angle, far-field sound emissions. Azimuthal rings of six microphones recorded pressure fluctuations on a conical surface in the jet near field while an azimuthal ring of three microphones recorded fluctuations in the far field at θ = 20° and R/D = 47.1. Recent measurements have shown close agreement between the velocity fluctuations up to the end of the potential core of the currently studied jet and predictions from the linear Parabolised Stability Equations (PSE), indicating the presence of linear wavepackets in the jet velocity field. Solutions of the Linearised Euler Equations (LEE) reported in the present paper also show good agreement with measurements, and provide a first step toward a time-domain description of the said wavepackets. Though the agreement for PSE in the velocity field breaks down downstream of the potential core, Proper Orthogonal Decomposition (POD) of the current results shows that the wavepackets do persist in this region and are clearly apparent in the near pressure field. Attention is then turned to establishing a relationship between these wavepackets and the radiated sound by comparing simultaneously-obtained measurements of the far-field pressure both directly to the near-field signature as well as to numerical predictions of the far-field emissions available from a recent technique using a tailored Green's function. The direct comparisons are made by correlations between the POD modes and the far-field sound. The first POD mode captures most of the flow energy for the frequency range studied, and the correlation between this mode and the far field is nearly identical to the correlation using the full near-field signal. Higher POD modes also show significant correlation to the far field with a different space-time structure than the first mode. The Green's function predictions are performed both statistically and in the time domain, and though they are shown to be valid for a near-field array with a long axial extent, the experimental limitation of a shorter array (0.5 ≤ x/D ≤ 8.9), which truncates the wavepacket source in the calculations, causes inaccurate predictions for the experimental data. This error is thought to be the result of a spurious source introduced by the truncation that interferes both constructively and destructively with the wavepacket source. A validation problem shows that this error would be smaller for a higher-M jet.
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机译:本文详细说明了近场压力波动之间的关系的关系,余量自由射流(0.4≤m≤0.6)及其低角度,远场声音排放。六个麦克风的方位角响起在射流近场的圆锥形表面上的压力波动,而三角环的三个麦克风在θ= 20°和R / D = 47.1的远场中的波动。最近的测量结果显示了当前研究的射流的潜在核心结束的速度波动与来自线性抛光稳定性方程(PSE)的预测的速度波动之间的紧密协议,表示喷射速度场中的线性波形的存在。本文报告的线性化欧拉方程(LEE)的解决方案还显示出与测量的良好一致性,并提供朝向所述波波皮的时域描述的第一步。虽然在速度场中的PSE协议下降到潜在核心的下游,但是当前结果的适当正交分解(POD)表明,在该区域中,波袋在该区域中持续存在,并且在近压场中显而易见。然后,通过将远场压力直接与近场签名的远场压力同时获得的远场压力的测量结果相比,对这些波膜和辐射声音之间的关系以及从A的远场排放的数值预测相比最近使用量身定制的绿色功能的技术。直接比较是通过豆荚模式与远场声音之间的相关性进行的。第一POD模式捕获所研究的频率范围的大部分流量,并且该模式与远场之间的相关性与使用全近场信号的相关性几乎相同。较高的POD模式还显示与远场的显着相关性,与第一模式不同的时空结构。绿色的功能预测是在统计上和时域中执行的,尽管它们被显示为具有长轴向范围的近场阵列,但较短阵列的实验限制(0.5≤x/d≤8.9)截断计算中的WavePacket源,导致实验数据的预测不准确。被认为是由截断引入的虚假来源的结果,该截断与波波皮源有建设性和破坏性地干扰。验证问题表明,对于更高M喷射,此错误将更小。
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