Doc.:1900.7-11/0006r0 SubmissionSlide 1 13/08/2015 Slide 1 IEEE 1900.7 White Space Radio Use Cases Notice: This document has been prepared to assist IEEE.

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doc.: /0006r0 SubmissionSlide 1 13/08/2015 Slide 1 IEEE White Space Radio Use Cases Notice: This document has been prepared to assist IEEE DYSPAN SC. It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein. Release: The contributor grants a free, irrevocable license to the IEEE to incorporate material contained in this contribution, and any modifications thereof, in the creation of an IEEE Standards publication; to copyright in the IEEE’s name any IEEE Standards publication even though it may include portions of this contribution; and at the IEEE’s sole discretion to permit others to reproduce in whole or in part the resulting IEEE Standards publication. The contributor also acknowledges and accepts that this contribution may be made public by IEEE DYSPAN SC. Patent Policy and Procedures: The contributor is familiar with the IEEE Patent Policy and Procedures, including the statement "IEEE standards may include the known use of patent(s), including patent applications, provided the IEEE receives assurance from the patent holder or applicant with respect to patents essential for compliance with both mandatory and optional portions of the standard." Early disclosure to the Working Group of patent information that might be relevant to the standard is essential to reduce the possibility for delays in the development process and increase the likelihood that the draft publication will be approved for publication. Please notify the Chair as early as possible, in written or electronic form, if patented technology (or technology under patent application) might be incorporated into a draft standard being developed within IEEE DYSPAN SC. If you have questions, contact the IEEE Patent Committee Administrator at. Date: Feb Authors:

doc.: /0006r0 SubmissionSlide 2 Summary of Use Cases  Four categories of use cases are identified ■ Wireless backbone networks Wireless access backbone network Wireless mesh backbone network High speed vehicular backbone network Rural broadband network ■ Land fixed/mobile networks Smart home network Digital signage network Transportation logistics network Wireless access network ■ Maritime networks Maritime wireless access network Inter-ship mesh network Maritime grid network ■ Home/office networks Home/office Network 13/08/2015

doc.: /0006r0 SubmissionSlide 3 I. Wireless Backbone Networks  This category includes three use cases ■ Wireless Access Backbone Network High data rate wireless access network serving as a backbone network for fixed stations that provide wireless/wired access service to their users ■ Wireless Mesh Backbone Network High data rate mesh backbone network connecting fixed stations that provide wireless/wired access service to their users ■ High Speed Vehicle Backbone Network High data rate backbone network for high speed vehicles ■ Rural broadband network Broadband access to homes 13/08/2015

doc.: /0006r0 SubmissionSlide 4 Wireless Access Backbone Network  White space radio is used to provide high data rate wireless access network serving as a backbone network for fixed stations that provide wireless/wired access service to their users  Potential applications ■ Campus connectivity ■ Enterprise connectivity ■ Dynamic backhaul ■ Quick-to-deploy temporary networks 13/08/2015

doc.: /0006r0 SubmissionSlide 5 Wireless Access Backbone Network 13/08/2015

doc.: /0006r0 SubmissionSlide 6 Wireless Access Backbone Network 13/08/2015 Propagation environment Outdoor LOS, NLOS Outdoor to indoor LOS, NLOS Expected data rate per terminal (1)30 Mbps Maximum transmission range10 km Maximum mobility speedfixed Tolerable delayHigh Security levelHigh Number of terminals per base station (2)5-10 (1) Expected data rate per terminal is the maximum rate that a terminal is able to achieve theoretically. (2) Number of terminals per base station is the number of connected devices (active and in sleep mode).

doc.: /0006r0 SubmissionSlide 7 Wireless Access Backbone Network  WS Radio Base Station is fixed  WS Radio Terminals are fixed 13/08/2015

doc.: /0006r0 SubmissionSlide 8 Wireless Mesh Backbone Network  White space radio is used to provide high data rate mesh backbone network connecting fixed stations that provide wireless/wired access service to their users  Potential applications ■ Campus connectivity ■ Enterprise connectivity ■ Quick-to-deploy temporary networks 13/08/2015

doc.: /0006r0 SubmissionSlide 9 Wireless Mesh Backbone Network 13/08/2015

doc.: /0006r0 SubmissionSlide 10 Wireless Mesh Backbone Network 13/08/2015

doc.: /0006r0 SubmissionSlide 11 Wireless Mesh Backbone Network  WS Radio Terminals are fixed 13/08/2015

doc.: /0006r0 SubmissionSlide 12 High Speed Vehicle Backbone Network  White space radio is used to provide high data rate backbone network for high speed vehicles  Potential applications ■ Backbone network for high-speed trains ■ Backbone network for long distance buses 13/08/2015

doc.: /0006r0 SubmissionSlide 13 High Speed Vehicle Backbone Network 13/08/2015

doc.: /0006r0 SubmissionSlide 14 High Speed Vehicle Backbone Network 13/08/2015

doc.: /0006r0 SubmissionSlide 15 High Speed Vehicle Backbone Network  WS Radio Base Station is fixed  WS Radio Relay Stations are fixed  WS Radio Terminals are mobile 13/08/2015

doc.: /0006r0 SubmissionSlide 16 Rural Broadband network  White space radio is used to provide broadband access to homes.  Base stations are fixed  Home terminals are fixed  Distribution around homes is not part of this use case (possibly home/office network solution later in this document)

doc.: /0006r0 SubmissionSlide 17 Rural Broadband network

doc.: /0006r0 SubmissionSlide 18 Rural Broadband network Propagation environment Outdoor LOS, NLOS Outdoor to indoor LOS, NLOS (possibly) Expected data rate per terminal30 Mbps Maximum transmission range10 km Maximum mobility speedfixed Tolerable delayHigh Security levelHigh Number of terminals per base station30

doc.: /0006r0 SubmissionSlide 19 II. Land Fixed/Mobile Networks  This category includes three use cases ■ Smart Home Networks Low data rate network for collecting data from low power consumption stations gathering measurements from utility devices (e.g., gas, water, and electricity meters) ■ Digital Signage Network Distribution network for digital signs ■ Transportation Logistics Network Low data rate network for tracking and controlling mobile stations (e.g., post delivery vehicles) ■ Mobile Wireless Access Network Providing wireless access to mobile stations 13/08/2015

doc.: /0006r0 SubmissionSlide 20 Smart Home Network  White space radio is used to provide low data rate network for collecting data from low power consumption stations gathering measurements from devices, e.g., gas, water, electricity meters, and to control such devices from a server  Potential applications ■ Smart metering ■ Monitoring and control 13/08/2015

doc.: /0006r0 SubmissionSlide 21 Smart Home Networks 13/08/2015

doc.: /0006r0 SubmissionSlide 22 Smart Home Network 13/08/2015

doc.: /0006r0 SubmissionSlide 23 Smart Home Network  WS Radio Base Station is fixed  WS Radio Relay Stations are fixed  WS Radio Terminals are fixed 13/08/2015

doc.: /0006r0 SubmissionSlide 24 Digital Signage Network  White space radio is used to provide data distribution network for digital signs  Potential applications ■ Digital signage 13/08/2015

doc.: /0006r0 SubmissionSlide 25 Digital Signage Network 13/08/2015

doc.: /0006r0 SubmissionSlide 26 Digital Signage Network 13/08/2015

doc.: /0006r0 SubmissionSlide 27 Digital Signage Network  WS Radio Base Station is fixed  WS Radio Relay Stations are fixed  WS Radio Terminals are fixed 13/08/2015

doc.: /0006r0 SubmissionSlide 28 Transportation Logistics Network  White space radio is used to provide low data rate network for tracking and controlling mobile stations, e.g., post delivery vehicles  Potential applications ■ Public transportation logistics ■ Control and management of postal and delivery services 13/08/2015

doc.: /0006r0 SubmissionSlide 29 Transportation Logistics Network 13/08/2015

doc.: /0006r0 SubmissionSlide 30 Transportation Logistics Network 13/08/2015

doc.: /0006r0 SubmissionSlide 31 Transportation Logistics Network  WS Radio Base Station is fixed  WS Radio Relay Stations are fixed  WS Radio Terminals are mobile 13/08/2015

doc.: /0006r0 SubmissionSlide 32 Mobile Wireless Access Network  White space radio is used to provide wireless access to mobile stations  Potential applications ■ Mobile wireless access ■ Cellular network extension to white space 13/08/2015

doc.: /0006r0 SubmissionSlide 33 Mobile Wireless Access Network 13/08/2015

doc.: /0006r0 SubmissionSlide 34 Mobile Wireless Access Network 13/08/2015

doc.: /0006r0 SubmissionSlide 35 Mobile Wireless Access Network  WS Radio Base Station is fixed  WS Radio Relay Stations are fixed  WS Radio Terminals are mobile and pedestrian 13/08/2015

doc.: /0006r0 SubmissionSlide 36 III. Maritime Networks  This category includes three use cases ■ Maritime Wireless Access Network Providing wireless access to ships and connecting ships with each other ■ Inter-ship Mesh Network Mesh network connecting stations located on ships ■ Maritime Grid Network Low data rate network collecting data from marine environment monitoring stations, oil/gas platforms, etc 13/08/2015

doc.: /0006r0 SubmissionSlide 37 Maritime Wireless Access Network  White space radio is used to provide maritime wireless access network  Potential applications ■ Wireless access for ship crew and passengers ■ Fleet and seaport management ■ Inter-ship communications 13/08/2015

doc.: /0006r0 SubmissionSlide 38 Maritime Wireless Access Network 13/08/2015

doc.: /0006r0 SubmissionSlide 39 Maritime Wireless Access Network 13/08/2015

doc.: /0006r0 SubmissionSlide 40 Maritime Wireless Access Network  WS Radio Base Station is fixed  WS Radio Terminals are mobile 13/08/2015

doc.: /0006r0 SubmissionSlide 41 Inter-ship Mesh Network  White space radio is used to provide mesh network connecting stations located on ships  Potential applications ■ Fleet management ■ Inter-ship communications ■ Disaster rescue ■ Anti-piracy 13/08/2015

doc.: /0006r0 SubmissionSlide 42 Inter-ship Mesh Network 13/08/2015

doc.: /0006r0 SubmissionSlide 43 Inter-ship Mesh Network 13/08/2015

doc.: /0006r0 SubmissionSlide 44 Inter-ship Mesh Network  WS Radio Terminals are mobile 13/08/2015

doc.: /0006r0 SubmissionSlide 45 Maritime Grid Network  White space radio is used to provide low data rate network collecting data from marine environment monitoring stations, oil/gas platforms, etc  Potential applications ■ Seaport management ■ Control and management of oil platforms, sea farms ■ Marine environment monitoring and data collection 13/08/2015

doc.: /0006r0 SubmissionSlide 46 Maritime Grid Network 13/08/2015

doc.: /0006r0 SubmissionSlide 47 Maritime Grid Network 13/08/2015 Propagation environmentOutdoor LOS, NLOS Expected data rate per terminal10 Mbps Maximum transmission range20 km Maximum mobility speedFixed/Mobile Tolerable delayHigh Security levelHigh Number of terminals per base station

doc.: /0006r0 SubmissionSlide 48 Maritime Grid Network 13/08/2015  WS Radio Base Station is fixed  WS Radio Relay Stations are fixed  WS Radio Terminals are fixed, mobile

doc.: /0006r0 SubmissionSlide 49 Indoor Networks  This category includes one use case ■ Indoor Network Providing wireless access inside office or home 13/08/2015

doc.: /0006r0 SubmissionSlide 50 Home/Office Network  White space radio is used to provide wireless access inside home or office  Potential applications ■ Wireless access inside office ■ Wireless access inside home ■ Inside-to-outside coverage 13/08/2015

doc.: /0006r0 SubmissionSlide 51 Home/Office Network 13/08/2015

doc.: /0006r0 SubmissionSlide 52 Indoor Network 13/08/2015 Propagation environment Indoor LOS, NLOS Outdoor to indoor LOS, NLOS Expected data rate per terminal20 Mbps Maximum transmission range300 m Maximum mobility speed4 km/h Tolerable delayMedium Security levelMedium Number of terminals per base station1-10

doc.: /0006r0 SubmissionSlide 53 Indoor Network  WS Radio Base Station is fixed  WS Radio Terminals are pedestrian 13/08/2015

doc.: /0006r0 SubmissionSlide 54 13/08/2015 The contributions of R. MacKenzie have the following acknowledgement: “The research leading to this presentation was derived from the European Community’s Seventh Framework Programme (FP7) under Grant Agreement number (QoSMOS)”