Tanker Vessel Inner Spaces WLAN Development and Quality of Experience Study for Video Streaming

This paper studies the establishment of a reliable communication link between the below deck spaces of an ocean going tanker vessel and the managing office ashore suitable to support an Augmented Reality based Remote Assistance Platform (AR-RAP). Results are presented regarding a WLAN implementation for the below deck spaces along with the Quality of Experience (QoE) of video streaming tests with the headquarters. The implemented WLAN uses IEEE 802.11 n, ac protocols, and utilizes MIMO $3 \times 2$ Transmit Beamforming $( \mathrm {T}\times $ BF) and $2 \times 3$ Spatial Division Multiplexing (SDM) through the respective MIMO Access Points (APs). As results indicate, the proposed architecture has proven to be robust and without signal fluctuation, despite the high reverberant environment of the vessel's engine room. The bottleneck of the communication link proved to be the Satellite link, due to the limited available bandwidth and the high inherent latency.

[1]  G.B. Tait,et al.  Electromagnetic environment characterization of below-deck spaces in ships , 2008, 2008 IEEE International Symposium on Electromagnetic Compatibility.

[2]  Lena Schwartz Next Generation Wireless Lans 802 11n And 802 11ac , 2016 .

[3]  Gregory B. Tait,et al.  On modeling wireless radio-frequency energy propagation in below-deck ship spaces , 2014, 2014 IEEE International Symposium on Electromagnetic Compatibility (EMC).

[4]  G. Grunfelder,et al.  Measurements and path loss models for shipboard environments at 2.4 GHz , 2011, 2011 41st European Microwave Conference.

[5]  Pablo César,et al.  1Mbps is enough: Video quality and individual idiosyncrasies in multiparty HD video-conferencing , 2016, 2016 Eighth International Conference on Quality of Multimedia Experience (QoMEX).

[6]  Yanli Xu,et al.  Quality of Service Provisions for Maritime Communications Based on Cellular Networks , 2017, IEEE Access.

[7]  M. Girish Chandra,et al.  SMART: secure mobile augmented reality for tele-assistance , 2015, 2015 Asia Pacific Conference on Multimedia and Broadcasting.

[8]  Krzysztof Gierlowski,et al.  Broadband communication solutions for maritime ITSs: Wider and faster deployment of new e-navigation services , 2017, 2017 15th International Conference on ITS Telecommunications (ITST).

[9]  Ronald Azuma,et al.  Recent Advances in Augmented Reality , 2001, IEEE Computer Graphics and Applications.

[10]  Jean-Marie Bonnin,et al.  Quality of Experience Measurements for Video Streaming over Wireless Networks , 2009, 2009 Sixth International Conference on Information Technology: New Generations.

[11]  P. Uthansakul,et al.  Experiments with a Low-Profile Beamforming MIMO System for WLAN Applications , 2011, IEEE Antennas and Propagation Magazine.

[12]  Chong Eng Tan,et al.  Enhanced compression scheme for high latency networks to improve quality of service of real-time applications , 2010, 8th Asia-Pacific Symposium on Information and Telecommunication Technologies.

[13]  David Brunnenmeyer,et al.  Ka and Ku operational considerations for military SATCOM applications , 2012, MILCOM 2012 - 2012 IEEE Military Communications Conference.

[14]  D. W. F. van Krevelen,et al.  A Survey of Augmented Reality Technologies, Applications and Limitations , 2010, Int. J. Virtual Real..