doc.: IEEE /66r0 Submission June, 2011 Chang-Woo Pyo, NICTSlide 1 Review of & Comparison with Smart Grid and Critical Infrastructure Monitoring IEEE P Wireless RANs Date: Authors: Notice: This document has been prepared to assist IEEE 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 Patent Policy and Procedures: The contributor is familiar with the IEEE 802 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 Chairhttp://standards.ieee.org/guides/bylaws/sb-bylaws.pdf Wendong HuWendong Hu 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 the IEEE Working Group. If you have questions, contact the IEEE Patent Committee Administrator at

doc.: IEEE /66r0 Submission June, 2011 Chang-Woo Pyo, NICTSlide 2 Abstract This review document provides an overview of Standards that are g, k and SG4TV, which may have some relevancies with Smart Grid and Critical Infrastructure Monitoring Study Group Also, this provides the example usages for Smart Grid and Critical Infrastructure Monitoring Study Group, and the differences and similarities between and for smart grid and critical infrastructure monitoring

doc.: IEEE /66r0 Submission Title g IEEE Standard for Local and Metropolitan Area Networks Part 15.4: Low Rate Wireless Personal Area Networks (LR-WPANs) Amendment: Physical Layer (PHY) Specifications for Low Data Rate Wireless Smart Metering Utility Networks k IEEE Standard for Local and Metropolitan Area Networks - Part 15.4: Wireless Medium Access Control (MAC) and Physical Layer (PHY) Specifications for Low Rate Wireless Personal Area Networks (WPANs) Amendment - Physical Layer (PHY) Specifications for Low Energy, Critical Infrastructure Monitoring Networks (LECIM) SG4TV Standard for Information Technology - Telecommunications and Information Exchange Between Systems - Local and Metropolitan Area Networks - Specific Requirements - Part 15.4: Wireless Medium Access Control (MAC) and Physical Layer (PHY) Specifications for Low Rate Wireless Personal Area Networks (WPANs)Amendment: TV White Space PHY Layer June 2011 Chang-Woo Pyo, NICTSlide 3

doc.: IEEE /66r0 Submission PAR Scope (1/2) June 2011 Chang-Woo Pyo, NICTSlide g This Standard defines an amendment to IEEE It addresses principally outdoor Low Data Rate Wireless Smart Metering Utility Network requirements. It defines an alternate PHY and only those MAC modifications needed to support its implementation. Specifically, the amendment supports all of the following: Operation in any of the regionally available license exempt frequency bands, such as 700MHz to 1GHz, and the 2.4 GHz band. Data rate of at least 40 kbits per second but not more than 1000 kbits per second. Achieve the optimal energy efficient link margin given the environmental conditions encountered in Smart Metering deployments. Principally outdoor communications PHY frame sizes up to a minimum of 1500 octets Simultaneous operation for at least 3 co-located orthogonal networks Connectivity to at least one thousand direct neighbors characteristic of dense urban deployment Provides mechanisms that enable coexistence with other systems in the same band(s) including IEEE , and systems

doc.: IEEE /66r0 Submission PAR Scope (2/2) k This standard is an amendment to IEEE It addresses principally those applications such as critical infrastructure monitoring. It defines an alternate PHY and only those MAC modifications needed to support its implementation. The amendment supports: ' *(1) Operation in any of the regionally available licensed, license exempt, and special purpose frequency bands ' *(2) Simultaneous operation for at least 8 co-located orthogonal networks ' *(3) Application data rate of less than 40 kbits per second ' *(4) Propagation path loss of at least 120 dB ' *(5) >1000 endpoints per mains powered infrastructure ' *(6) Asymmetric application data flow ' *(7) Extreme difference in capabilities and performance between endpoint devices and coordinating devices (collectors) ' -coordinator may support all standardized modulations (MCS) and data rates ' -coordinator may be required to support antenna diversity or antenna beam steering ' - end point must be able to conserve energy ' *(8) Reliable operation in dramatically changing environments (no control over environment) This amendment also provides mechanisms that (9) enable coexistence with other systems in the same band(s) including IEEE , and systems SG4TV This amendment specifies a physical layer for meeting TV white space regulatory requirements and also any necessary MAC changes needed to support this physical layer. The amendment enables operation in the available TV white space, supporting typical data rates in the 40 kbits per second to 2000 kbits per second range, to realize optimal and power efficient device command and control applications. It supports accepted methods of TV White Space coexistence in existence at the time of development. June 2011 Chang-Woo Pyo, NICTSlide 5

doc.: IEEE /66r0 Submission PAR Purpose June 2011 Chang-Woo Pyo, NICTSlide g To provide a global standard that facilitates very large scale process control applications such as the utility smart-grid network. This amendment supports large, geographically diverse networks with minimal infrastructure. Smart Metering Utility Networks can potentially contain millions of fixed endpoints. The communication range, robustness, and coexistence characteristics required for this class of application have not been met with existing 802 standards k The purpose of this amendment is to facilitate point to multi-thousands of points communications for critical infrastructure monitoring devices. The amendment addresses the application's user needs of minimal network infrastructure, and enables the collection of scheduled and event data from a large number of non-mains powered end points that are widely dispersed, or are in challenging propagation environments. To facilitate low energy operation necessary for multi-year battery life, the amendment minimizes network maintenance traffic and device wake durations. In addition, the amendment addresses the changing propagation and interference environments SG4TV The purpose of this amendment is to allow wireless networks to take advantage of the TV white space spectrum for use in large scale device command and control applications.

doc.: IEEE /66r0 Submission 5C g k SG4TV Broad Market Potential Compatibility Distinct IdentityThe : optimized for high data rates along with support for star network topologies with centralized control : optimized for high data rate, point-to-point and point-to- multipoint network topologies, licensed band, TDM The : support frame sizes of 1500 bytes in length and error detection of a two byte CRC g (WNAN) requirements : low data rate (40kbps), unlicensed band, burst and asynchronous upstream traffic, star-topology as well as peer-to-peer IEEE will not adequately support the low energy critical infrastructure monitoring application requirements The current IEEE M2M PAR calls for changes to the MAC, and no substantial change to its PHY. it will not meet the large path loss, minimal infrastructure requirements, and multi- year battery life required by LECIM applications. IEEE is intended to provide broadband services to rural subscribers, which does not address the need for multiyear battery life. IEEE is designed for higher data rates which limit both range and battery life to less than that required by LECIM applications. There are no other IEEE 802 projects, utilizing unused TV channels, specifically addressing low data rate operation optimized for use in device command and control applications. Technical Feasibility Economic Feasibility June 2011 Chang-Woo Pyo, NICTSlide 7

doc.: IEEE /66r0 Submission Usages June 2011 Chang-Woo Pyo, NICTSlide g k SG4TV New SG Meter Reading in Japan Outdoor Control & Monitoring Infrastructure Asset Management Smart Grid Eco- System Water & Sewerage Management Infrastructure Monitoring Water leak detection Sewer monitoring Bridge/structural integrity monitoring Streetlight control systems Fault Circuit Indicators Soil monitoring Oil & gas pipeline monitoring Transportation & Asset tracking Public transport tracking Cargo container monitoring Railroad condition monitoring Traffic congestion monitoring Security & Life Safety Gas/hazardous material detection Perimeter security Border surveillance Medical alert for at-risk populations First responder tracking Utility smart grid networks Utility monitoring and control Mobile utility control and data collection (a) Regional Area Smart Grid/Metering: support Low Energy & Complexity CPEs (b) Emergency Temporary Broadband Infrastructure : Ad hoc connecting among portable CPEs (c) Critical Infrastructure/Hazard Monitoring: Support very large number of monitoring CPEs (d) Remote Medical Service: Support remote medical service with high QoS in a rural residence area

doc.: IEEE /66r0 Submission Summary – Review, Differences and Similarities June 2011 Chang-Woo Pyo, NICTSlide g k SG4TV New SG 1Amendment PHY Amendment PHY and MAC Amendment 2Operating Frequency License-exempt (700MHz~1GHz, 2.4GHz) Licensed, License-exempt, Any frequency to attempt TVWS frequency 3Usage Smart Utility Network Critical Infrastructure Sensing, Monitoring Command and control application Sensors / Meters ITS Regional area smart grid/metering Emergency broadband Critical Infrastructure/Hazard monitoring Remote medical service 4Coverage WPAN, Neighbor Area Network (NAN) WPAN WRAN (Several tens of Km, 20~30Km) 5Transmission Power Less power consumption (up to 1W some regulatory domain) Low energy transmission? Fixed high power (4W) in US, Portable/Mobile Power (100mW, 40mW) in US 6Transmission Rate > 40Kbps < 1000Kbps Less than 40kbps> 40Kbps < 2000Kbps From several kbps (one stream) to several Mbps (multi-streams) 7Network topology Peer-to-multihop peer Point-to-multipoint (star) Point-to-Multipoints Star, Peer-to-Peer ? Infrastructure Mode, Point-to-Multipoints, Support peer-to-peer connection 8Available Devices a large number of outdoor devices (>1000 devices) > 1000 devices?More than 256 9Coexistence 11, 15, 16 coexistence 11, 16, 15 coexistence11af, 22 coexistence11af, 15 4TV coexistence 10else--TVDB Channel Access, Geolocation

doc.: IEEE /66r0 Submission Conclusion As amendment for , New SG –consider to support low energy consumption and complexity CPEs –considers to support ad hoc connection (such as peer-to-peer connection, multi-hop connection) among portable CPEs for emergency broadband infrastructure –considers to support very large number of CPEs with low energy and complexity for monitoring a regional area –considers to support high reliability and QoS for critical applications such as medical service, hazard monitoring, etc Comparing to , uniqueness of New SG –is able to provide a very large service area and support a very large number of devices effectively –is able to provide a variable power level from low to high depending on the capability of CPE, which adopts usage applications efficiently –is able to provide a variable data rate from low to high depending on usages (Network backhaul – Several Mbps, Meter/Monitoring – Several Kbps) –is able to extend a current STD easily and efficiently to smart grid applications on TV white space frequency June, 2011 Chang-Woo Pyo, NICTSlide 10

doc.: IEEE /66r0 Submission References g PAR k PAR SG4TV PAR June 2011 Chang-Woo Pyo, NICTSlide 11