Resilience against Shipping Noise and Interference in Low-Power Acoustic Underwater Communication

Underwater Wireless Sensor Networks (UWSNs) and micro Autonomous Underwater Vehicles ($\mu \mathbf{AUVs}$) enable diverse underwater monitoring and service applications; e.g., observation of water quality or identification of pollution sources. Reliable underwater communication for data transmission between sensors, $\mu\mathbf{AUVs}$ and base stations is required and typically acoustic. However, vessels and $\mu\mathbf{AUVs}$ produce noise, disturbing the acoustic data transmission. Additionally, in networks there is potentially a risk of packet interference. This paper discusses the resilience against noise and interference of low-power acoustic underwater modems in a network. We used the smartPORT Acoustic Underwater Modem (AHOI modem) to analyze signal processing and modulation schemes in a concrete case. The AHOI modem modem is a small, low-power and low-cost modem, which was developed for UWSNs and integration into $\mu\mathbf{AUVs}$. Based on our findings, we evaluate the resilience in simulations and through real-world experiments in a marina. In general, the results are useful to design and simulate low-power acoustic underwater communication.

[1]  Alessandro Casavola,et al.  SeaModem: A low-cost underwater acoustic modem for shallow water communication , 2015, OCEANS 2015 - Genova.

[4]  Roberto Petroccia,et al.  Underwater Acoustic Modems (S2CR Series) for Synchronization of Underwater Acoustic Network Clocks During Payload Data Exchange , 2016, IEEE Journal of Oceanic Engineering.

[5]  Christian Renner,et al.  Acoustic modem for micro AUVs: design and practical evaluation , 2016, WUWNet.

[6]  Milica Stojanovic,et al.  Underwater sensor networks: applications, advances and challenges , 2012, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[7]  Michele Zorzi,et al.  Implementation of AUV and ship noise for link quality evaluation in the DESERT underwater framework , 2018, WUWNet.

[8]  Christian Renner,et al.  A practical guide to chirp spread spectrum for acoustic underwater communication in shallow waters , 2018, WUWNet.

[9]  Nakano Masaki,et al.  Harbor Monitoring Network System for Detecting Suspicious Objects Approaching Critical Facilities in Coastal Areas , 2015 .

[10]  Benjamin Meyer,et al.  Cooperative swarm behaviour for in situ underwater environmental measurements , 2017, OCEANS 2017 - Aberdeen.

[11]  Milica Stojanovic,et al.  Underwater acoustic communication channels: Propagation models and statistical characterization , 2009, IEEE Communications Magazine.

[12]  Paolo Casari,et al.  The DESERT underwater framework v2: Improved capabilities and extension tools , 2016, 2016 IEEE Third Underwater Communications and Networking Conference (UComms).

[14]  Alex Borges Vieira,et al.  HydroNode: A low cost, energy efficient, multi purpose node for underwater sensor networks , 2012, 37th Annual IEEE Conference on Local Computer Networks.

[15]  E Gallimore,et al.  The WHOI micromodem-2: A scalable system for acoustic communications and networking , 2010, OCEANS 2010 MTS/IEEE SEATTLE.

[16]  Richard P. Hodges Underwater Acoustics: Analysis, Design and Performance of Sonar , 2010 .

[17]  Beatrice Tomasi,et al.  JANUS: the genesis, propagation and use of an underwater standard , 2010 .

[18]  Curt Schurgers,et al.  Design of a low-cost, underwater acoustic modem for short-range sensor networks , 2010 .

[19]  Axel Hackbarth,et al.  HippoCampus: A micro underwater vehicle for swarm applications , 2015, 2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).

[20]  R. Asariotis,et al.  Review of Maritime Transport, 2014 , 2010 .

[21]  Michele Zorzi,et al.  Underwater Acoustic Sensors Data Collection in the Robotic Vessels as-a-Service Project , 2019, OCEANS 2019 - Marseille.