Saved in:
Bibliographic Details
Main Authors: Rodriguez, Belman Jahir, Chevtchenko, Sergio F., Martinez, Marcelo Herrera, Bethi, Yeshwanth, Afshar, Saeed
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.00307
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912984093163520
author Rodriguez, Belman Jahir
Chevtchenko, Sergio F.
Martinez, Marcelo Herrera
Bethi, Yeshwanth
Afshar, Saeed
author_facet Rodriguez, Belman Jahir
Chevtchenko, Sergio F.
Martinez, Marcelo Herrera
Bethi, Yeshwanth
Afshar, Saeed
contents We introduce a U-net model for 360° acoustic source localization formulated as a spherical semantic segmentation task. Rather than regressing discrete direction-of-arrival (DoA) angles, our model segments beamformed audio maps (azimuth & elevation) into regions of active sound presence. Using delay-and-sum (DAS) beamforming on a custom 24-microphone array, we generate signals aligned with drone GPS telemetry to create binary supervision masks. A modified U-Net, trained on frequency-domain representations of these maps, learns to identify spatially distributed source regions while addressing class imbalance via the Tversky loss. Because the network operates on beamformed energy maps, the approach is inherently array-independent and can adapt to different microphone configurations and can be transferred to different microphone configurations with minimal adaptation. The segmentation outputs are post-processed by computing centroids over activated regions, enabling robust DoA estimates. Our dataset includes real-world open-field recordings of a DJI Air 3 drone, synchronized with 360° video and flight logs across multiple dates and locations. Experimental results show that U-net generalizes across environments, providing improved angular precision, offering a new paradigm for dense spatial audio understanding beyond traditional Sound Source Localization (SSL). We additionally validate the same beamforming-plus-segmentation formulation on the DCASE 2019 TAU Spatial Sound Events benchmark, showing that the approach generalizes beyond drone acoustics to multiclass Sound Event Localization and Detection (SELD) scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2508_00307
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Acoustic Imaging for UAV Detection: Dense Beamformed Energy Maps and U-Net SELD
Rodriguez, Belman Jahir
Chevtchenko, Sergio F.
Martinez, Marcelo Herrera
Bethi, Yeshwanth
Afshar, Saeed
Audio and Speech Processing
Artificial Intelligence
Sound
Signal Processing
We introduce a U-net model for 360° acoustic source localization formulated as a spherical semantic segmentation task. Rather than regressing discrete direction-of-arrival (DoA) angles, our model segments beamformed audio maps (azimuth & elevation) into regions of active sound presence. Using delay-and-sum (DAS) beamforming on a custom 24-microphone array, we generate signals aligned with drone GPS telemetry to create binary supervision masks. A modified U-Net, trained on frequency-domain representations of these maps, learns to identify spatially distributed source regions while addressing class imbalance via the Tversky loss. Because the network operates on beamformed energy maps, the approach is inherently array-independent and can adapt to different microphone configurations and can be transferred to different microphone configurations with minimal adaptation. The segmentation outputs are post-processed by computing centroids over activated regions, enabling robust DoA estimates. Our dataset includes real-world open-field recordings of a DJI Air 3 drone, synchronized with 360° video and flight logs across multiple dates and locations. Experimental results show that U-net generalizes across environments, providing improved angular precision, offering a new paradigm for dense spatial audio understanding beyond traditional Sound Source Localization (SSL). We additionally validate the same beamforming-plus-segmentation formulation on the DCASE 2019 TAU Spatial Sound Events benchmark, showing that the approach generalizes beyond drone acoustics to multiclass Sound Event Localization and Detection (SELD) scenarios.
title Acoustic Imaging for UAV Detection: Dense Beamformed Energy Maps and U-Net SELD
topic Audio and Speech Processing
Artificial Intelligence
Sound
Signal Processing
url https://arxiv.org/abs/2508.00307