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1. Understanding end corrections and flow near the open end of a flue instrument

   https://doi.org/10.1121/10.0035834  

   Giordano, N (February 2025, The Journal of the Acoustical Society of America)

   Wind instruments containing a resonator (i.e., pipe) with an open end are expected to exhibit an acoustic standing wave characterized by a density oscillation whose amplitude falls to zero a short distance beyond the end of the resonator. An extrapolation of this amplitude based on the behavior inside the resonator yields an “effective” node of the standing wave (i.e., a point at which the extrapolated amplitude vanishes), and the distance from the end of the resonator to the location of this effective node (which is commonly referred to as simply a “node”) is known as the “end correction.” Recent work using a novel optical technique involving optical speckle patterns surprisingly suggested instead that a node is located inside the resonator with unexpected structure in the standing wave amplitude just beyond the end of the resonator. We have studied this problem by numerically solving the Navier-Stokes equations and find that the effective node of the density oscillation is located at the expected position outside the resonator with no unexpected structure in the functional form of the standing wave. We also show how pressure gradients and the flow pattern found near the end of the resonator can account for the unexpected behavior observed in the experiments. This sensitivity of optical interference effects to flow structure may give a new experimental way to investigate vorticity and other complex flows found in the mouthpiece of a musical instrument and in other situations. 

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2. Measuring the behavior of the acoustic standing wave exiting a flue organ pipe

   https://doi.org/10.1121/2.0001940  

   Schefter, Lauren Krebs; Coyle, Whitney L; Rokni, Eric; Cannaday, Ashley (January 2024, Proceedings of meetings on acoustics)

   Correctly predicting the playing frequencies of a musical instrument is dependent on the length of the resonator with the addition of an end correction. There are multiple theories describing this end correction, perhaps the simplest being that the end correction of a pipe is a physical extension of the sinusoidal pressure standing wave inside the pipe. However, recent optical imaging of the flow in a flue organ pipe found an unexpected exponential decay of pressure just outside of the pipe. This work looks to validate those findings acoustically. A flue organ pipe was played at the 1st, 5th, and 7th harmonics and the pressure just inside and immediately outside the end of the pipe played was measured using a zero-degree PU Match Microflown sound intensity probe. These measurements were fit to both exponential and sinusoidal curves and compared to the optical images. While an exponential trend is in fact apparent in some cases, the goodness-of-fit appears to be dependent on which harmonic is sounding. Future work includes exploration of a potential transitional region, assessing the impact of altered pipe geometry (both cross-sectional shape and size), and investigating potential sensor interference by using other measurement equipment. 

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3. Imaging acoustic standing waves in the presence of flowing gas

   https://doi.org/10.1364/AO.478777  

   Moore, Thomas_R; Baquerizo, Lucia; Fuse, Quinn; Kellison, Makayle_S (December 2022, Applied Optics)

   A method for imaging an acoustic standing wave in the presence of flowing gas is described. The optical power at the acoustic frequency in each pixel of a series of high-speed transmission electronic speckle pattern interferograms is used to map the steady-state pressure variations of an acoustic standing wave. The utility of the process is demonstrated by imaging the standing wave inside a transparent organ pipe. 

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4. Comparing classical and empirical end correction models using spatial pressure measurements in flue pipes

   https://doi.org/10.1051/aacus/2025058  

   Coyle, Whitney L; Schefter, Lauren K; Cannaday, Ashley E; Griffin, Max; Rokni, Eric (November 2025, Acta Acustica)

   This study evaluates end-correction behavior in flue organ pipes by comparing two models: the classical low-frequency expression of Levine and Schwinger and the empirical, frequency-dependent refinement of Davies et al. [Journal of Sound Vibration 72 (1980) 543–546], later revisited by Moore et al. [JASA Express Letters 3 (2023) 055002]. Using a Microflown probe, we performed high-resolution pressure measurements inside and outside circular and square pipes to capture the transition from standing-wave to radiating behavior. Sinusoidal variation within the end-correction region and 1/rdecay beyond were observed, consistent with theory. A two-region curve-fitting approach quantified each model’s accuracy. In the tested range (0.049 ≤ ka ≤ 0.377), both models reproduced the data with nearly identical accuracy (R² ≥ 0.997), with only a slight advantage for the classical form in one square-pipe case. Probe interference was evaluated and found negligible. While the analysis employs fixed end-correction values rather than a universal fit, it provides a controlled test of how well existing models capture the spatial pressure field near the pipe termination. Results indicate that both models are adequate in this regime, and that the radiating field beyondδfollows a robust 1/rdecay independent of model choice. 

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5. Enhancing Acoustic Emission Characteristics in Pipe-Like Structures with Gradient-Index Phononic Crystal Lens

   https://doi.org/10.3390/ma14061552  

   Okudan, Gorkem; Danawe, Hrishikesh; Zhang, Lu; Ozevin, Didem; Tol, Serife (March 2021, Materials)

   null (Ed.)

   Phononic crystals have the ability to manipulate the propagation of elastic waves in solids by generating unique dispersion characteristics. They can modify the conventional behavior of wave spreading in isotropic materials, known as attenuation, which negatively influences the ability of acoustic emission method to detect active defects in long-range, pipe-like structures. In this study, pipe geometry is reconfigured by adding gradient-index (GRIN) phononic crystal lens to improve the propagation distance of waves released by active defects such as crack growth and leak. The sensing element is designed to form a ring around the pipe circumference to capture the plane wave with the improved amplitude. The GRIN lens is designed by a special gradient-index profile with varying height stubs adhesively bonded to the pipe surface. The performance of GRIN lens for improving the amplitude of localized sources is demonstrated with finite element numerical model using multiphysics software. Experiments are conducted using pencil lead break simulating crack growth, as well as an orifice with pressured pipe simulating leak. The amplitude of the burst-type signal approximately doubles on average, validating the numerical findings. Hence, the axial distance between sensors can be increased proportionally in the passive sensing of defects in pipe-like geometries. 

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