Integrating Small Satellite Communication in an Autonomous Vehicle Network: A Case on Oceanography

Abstract Small satellites and autonomous vehicles have greatly evolved in the last few decades. Hundreds of small satellites have been launched with increasing functionalities, in the last few years. Likewise, numerous autonomous vehicles have been built, with decreasing costs and form-factor payloads. Here we focus on combining these two multifaceted assets in an incremental way, with an ultimate goal of alleviating the logistical expenses in remote oceanographic operations. The first goal is to create a highly reliable and constantly available communication link for a network of autonomous vehicles, taking advantage of the small satellite lower cost, with respect to conventional spacecraft, and its higher flexibility. We have developed a test platform as a proving ground for this network, by integrating a satellite software defined radio on an unmanned air vehicle, creating a system of systems, and several tests have been run successfully, over land. As soon as the satellite is fully operational, we will start to move towards a cooperative network of autonomous vehicles and small satellites, with application in maritime operations, both in-situ and remote sensing.

[1]  Richard Hobby An introduction to the Iridium(R) system , 1998 .

[2]  Barry G. Evans,et al.  Satellite communication systems , 1999 .

[3]  João Borges de Sousa,et al.  Using low cost open source UAVs for marine wild life monitoring - Field Report , 2013 .

[4]  Guoqing Zhou,et al.  UAV-based multi-sensor data fusion processing , 2010 .

[5]  Edward Z. Yang,et al.  Connecting the dots. , 1999, Nature genetics.

[6]  Sastri L. Kota,et al.  A survey on mobile satellite systems , 2010, Int. J. Satell. Commun. Netw..

[7]  Kenneth Y. Goldberg,et al.  Hydra: A framework and algorithms for mixed-initiative UAV-assisted search and rescue , 2008, 2008 IEEE International Conference on Automation Science and Engineering.

[8]  V. V. Spiridonov,et al.  Inmarsat systems and services , 1994, Proceedings of International Conference on Satellite Communications. ICSC'94.

[9]  João Borges de Sousa,et al.  Adaptive Consoles for Supervisory Control of Multiple Unmanned Aerial Vehicles , 2013, HCI.

[10]  Kanna Rajan,et al.  On small satellites for oceanography: A survey , 2015, 1512.07442.

[11]  Roberto Petroccia,et al.  Rapid Environmental Picture Atlantic exercise 2015: A field report , 2016, OCEANS 2016 MTS/IEEE Monterey.

[12]  John Ball,et al.  A method for examining the impact of interoperability on mission performance in a system-of-systems , 2010, 2010 IEEE Aerospace Conference.

[13]  Paulo Dias,et al.  The LSTS software toolchain for persistent maritime operations applied through vehicular ad-hoc networks , 2017, 2017 International Conference on Unmanned Aircraft Systems (ICUAS).

[14]  Ricardo Martins,et al.  The LSTS toolchain for networked vehicle systems , 2013, 2013 MTS/IEEE OCEANS - Bergen.

[15]  Gregg H. Gunsch,et al.  An overview of the IRIDIUM (R) low Earth orbit (LEO) satellite system , 1998, Proceedings of the IEEE 1998 National Aerospace and Electronics Conference. NAECON 1998. Celebrating 50 Years (Cat. No.98CH36185).

[16]  Reinhard German,et al.  Flying Ad-Hoc Network communication for detecting thermals: Feasibility and insights , 2013, Third International Conference on Innovative Computing Technology (INTECH 2013).

[17]  Alessandro Berni,et al.  An Underwater Convergence Layer for Disruption Tolerant Networking , 2011, 2011 Baltic Congress on Future Internet and Communications.