TY - GEN
T1 - Generating Underwater Acoustic Communication Channel Impulse Responses Using a Diffusion Model
AU - Zhuang, Yongjie
AU - Kari, Dariush
AU - Li, Zhengnan
AU - Stojanovic, Milica
AU - Singer, Andrew C.
N1 - This work was supported by the Office of Naval Research under Grant N00014-23-1-2852. The authors would like to thank James Preisig, Mandar Chitre, and Paul van Walree for their helpful discussions.
PY - 2024
Y1 - 2024
N2 - Underwater acoustic communication data is expensive to collect, often yielding experimental data sets that are sufficient for proof-of-concept analysis, but are insufficient for applications that demand orders of magnitude more channel realizations, such as data-driven methods for outage-capacity analysis, network simulation, or statistical regression of new communication algorithms. For such applications, a realistic synthetic dataset is a necessity for the successful generalization of data-driven underwater acoustic (UWA) communication systems. This paper investigates the application of diffusion models for UWA data augmentation for such systems. Diffusion models, as opposed to physics-based models such as BELLHOP or other acoustic propagation tools, extract the essential characteristics of the data without explicit knowledge of environmental parameters. We demonstrate the capability of such models by generating data whose multipath structure and spatiotemporal correlation match those of the Kauai ACOMMS MURI 2011 (KAM11) experiment.
AB - Underwater acoustic communication data is expensive to collect, often yielding experimental data sets that are sufficient for proof-of-concept analysis, but are insufficient for applications that demand orders of magnitude more channel realizations, such as data-driven methods for outage-capacity analysis, network simulation, or statistical regression of new communication algorithms. For such applications, a realistic synthetic dataset is a necessity for the successful generalization of data-driven underwater acoustic (UWA) communication systems. This paper investigates the application of diffusion models for UWA data augmentation for such systems. Diffusion models, as opposed to physics-based models such as BELLHOP or other acoustic propagation tools, extract the essential characteristics of the data without explicit knowledge of environmental parameters. We demonstrate the capability of such models by generating data whose multipath structure and spatiotemporal correlation match those of the Kauai ACOMMS MURI 2011 (KAM11) experiment.
KW - channel impulse re-sponses
KW - data augmentation
KW - diffusion model
KW - multipath
KW - Underwater acoustics
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U2 - 10.1109/UComms64662.2024.10847985
DO - 10.1109/UComms64662.2024.10847985
M3 - Conference contribution
AN - SCOPUS:85218219457
T3 - 2024 7th Underwater Communications and Networking Conference, UComms 2024
BT - 2024 7th Underwater Communications and Networking Conference, UComms 2024
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 7th Underwater Communications and Networking Conference, UComms 2024
Y2 - 3 September 2024 through 5 September 2024
ER -