Simulation Scenarios for Underground Mining in IEEE 802.11-18

This document discusses the motivation and proposed simulation scenarios for reliable communication in underground mining environments using Li-Fi technology. It addresses the shortcomings of Wi-Fi, IrDA, and BLE in such specialized settings and presents detailed scenarios for mining roadway and working face configurations to enhance safety and productivity.

• Underground Mining
• Simulation Scenarios
• IEEE 802.11-18
• Li-Fi Technology

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1. Sep 2018 doc.: IEEE 802.11-18/XXXX Simulation Scenario for Underground Mining Date: 2018-09-10 Authors: Name Jeong Gon Kim Company Korea Polytechnic University SYCA Address 237 Sangidaehak Ro, Si Heung, Kyunggi Do., 15073 Korea Phone +82103180410486 jgkim@kpu.ac.kr email Sooyoung Chang Mariappan Vinayagam Jae Sang Cha Seoul National University of Technology Submission Slide 1 Jeong Gon Kim, Korea Polytechnic University

2. Sep 2018 doc.: IEEE 802.11-18/XXXX Summary Motivation Simulation Scenario for Underground Mining Submission Slide 2 Jeong Gon Kim, Korea Polytechnic University

3. Sep 2018 doc.: IEEE 802.11-18/XXXX Motivation Current Status of Simulation Scenario In IEEE 802.11-18/1422r0, four kinds of simulation scenario are discussed for the specification In Industrial Wireless, it assumes the Robotic Work Cell (e.g., 8m x 10m x 7m or ~5m x 5m x 3m size) from IEEE802.11ax document It is needed to add simulation scenario for underground environment Li-Fi can be most effective in narrow and special indoor industrial environments, such as underground mining, subway and so on. Underground mining requires reliable communication, monitoring and tracking systems that guarantee safety and maximize productivity. Wi-Fi is easily affected by electromagnetism, IrDA isharmful to miner s eyes with too high power, BLE is more expensive and also needs high electronic storage. Submission Slide 3 Jeong Gon Kim, Korea Polytechnic University

4. Sep 2018 doc.: IEEE 802.11-18/XXXX System Model (b) Mine working face (a) Mining roadway Two separate scenario can be considered [2] Mining Roadway Mining Working Face Submission Slide 4 Jeong Gon Kim, Korea Polytechnic University

5. Sep 2018 doc.: IEEE 802.11-18/XXXX Topology L=5M W=2M LED O p t i c a l S i g n a l Lane Miner s Lamp H=3~5M D=1M Submission Slide 5 Jeong Gon Kim, Korea Polytechnic University

6. Sep 2018 doc.: IEEE 802.11-18/XXXX Proposed Set of Simulation Scenarios Traffic profile [tentative] Scenario Name Topology Management Channel Model E - Mining Roadway and Working Face e.g. ~2m x 5m x 3.7m (Mining Roadway) or ~2m x 5m x 4.7m (Working Face) size ~5s of STAs/AP, P2P pairs Underground (mining, subway, etc..) Path Loss & Delay Spread [2] 1 Managed Industrial Parameter Value Environment description 1 Mining Roadway and Mining Working Face Floors height : 3.7 m, 4.7 m Work cell size : 2 m x 5 m x 3.7 m 1 per work cell, installed at ceiling of underground mining, with multiple transceivers facing different directions N per AP, located on the top of the work cell boundary APs location STAs location Channel Model Path Loss and Delay Spread [2] Submission Slide 6 Jeong Gon Kim, Korea Polytechnic University

7. Aug 2018 doc.: IEEE 802.11-18/XXXX References 1. https://mentor.ieee.org/802.11/dcn/18/11-18-1422-00-TGbb-simulation -scenarios.ppt 2. J. Wang, A. Al-Kinani, J. Sun, W. Zhang and C. Wang, A Path Loss Channel Model for Visible Light Communications in Underground Mines , in Proc. ICCC 17, 2017. 3. J. Wang, A. Al-Kinani, W. Zhang, and C.-X. Wang, A new VLC channel model for underground mining environments, in Proc. IEEE IWCMC 17, Valencia, Spain, June 2017. 4. G. Wu and J. Zhang, Demonstration of a visible light communication system for underground mining applications, in Proc. IECT 16, Shanghai, China, pp. 1 7, June 2016. 5. S. Yarkan, S. Guzelgoz, H. Arslan, and R. R. Murphy, Underground mine communications: A survey, IEEE Commun. Surveys Tuts., vol. 11, no. 3, pp. 125 142, 2009, 3rd Quarter. Submission Slide 7 Jeong Gon Kim, Korea Polytechnic University