DOCSLIB.ORG

U.S.A. Proposals for the Work of the Conference

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
U.S.A. Proposals for the Work of the Conference INTERNATIONAL TELECOMMUNICATION UNION Document _E WORLD 9 February 2003 WRC-2003 RADIOCOMMUNICATION Original: English CONFERENCE Geneva, Switzerland, 9 June to 4 July 2003 PLENARY MEETING United States of America PROPOSALS FOR THE WORK OF THE CONFERENCE CONTENTS INTRODUCTION .....................................................................................................................................................3 UNITED STATES PROPOSALS..............................................................................................................................3 AGENDA ITEM 1.1: .................................................................................................................................................3 AGENDA ITEM 1.2: .................................................................................................................................................3 AGENDA ITEM 1.3: ...............................................................................................................................................14 AGENDA ITEM 1.4: ...............................................................................................................................................19 AGENDA ITEM 1.7: ...............................................................................................................................................23 1.7.1 POSSIBLE REVISION OF ARTICLE 25; ...........................................................................................................23 1.7.2 REVIEW OF THE PROVISIONS OF ARTICLE 19 CONCERNING THE FORMATION OF CALL SIGNS IN THE AMATEUR SERVICES IN ORDER TO PROVIDE FLEXIBILITY FOR ADMINISTRATIONS;.......................................................................27 1.7.3: REVIEW OF THE TERMS AND DEFINITIONS OF ARTICLE 1 TO THE EXTENT REQUIRED AS A CONSEQUENCE OF CHANGES MADE IN ARTICLE 25. ..............................................................................................................................28 AGENDA ITEM 1.8.1: ............................................................................................................................................28 AGENDA ITEM 1.9: ...............................................................................................................................................39 AGENDA ITEM 1.10.1: ..........................................................................................................................................40 AGENDA ITEM 1.11: .............................................................................................................................................46 AGENDA ITEM 1.12: .............................................................................................................................................48 PROPOSAL A (AGENDA ITEM 1.12)..........................................................................................................................48 PROPOSAL B (AGENDA ITEM 1.12)..........................................................................................................................50 PROPOSAL C (AGENDA ITEM 1.12)..........................................................................................................................51 PROPOSAL D (AGENDA ITEM 1.12)..........................................................................................................................55 PROPOSAL E (AGENDA ITEM 1.12) ..........................................................................................................................57 AGENDA ITEM 1.14: .............................................................................................................................................58 AGENDA ITEM 1.17: .............................................................................................................................................60 AGENDA ITEM 1.19: .............................................................................................................................................61 AGENDA ITEM 1.21: .............................................................................................................................................62 - 2 - USA AGENDA ITEM 1.22: .............................................................................................................................................63 AGENDA ITEM 1.24: .............................................................................................................................................67 AGENDA ITEM 1.25: .............................................................................................................................................70 AGENDA ITEM 1.26: .............................................................................................................................................78 AGENDA ITEM 1.28: .............................................................................................................................................87 AGENDA ITEM 1.29: .............................................................................................................................................88 PROPOSAL FOR ARTICLE 15, 22 AND RESOLUTION 78...............................................................................................88 PROPOSAL CONCERNING RESOLUTION 136 ..............................................................................................................90 AGENDA ITEM 1.30: .............................................................................................................................................93 AGENDA ITEM 1.31: .............................................................................................................................................95 PROPOSAL CONCERNING RESOLUTION 227 MSS AND THE METAIDS AND METSAT SERVICES .....................................95 PROPOSAL PURSUANT TO RESOLUTION 226..............................................................................................................97 AGENDA ITEM 1.37: .............................................................................................................................................99 AGENDA ITEM 1.38: ...........................................................................................................................................103 AGENDA ITEM 1.39: ...........................................................................................................................................107 AGENDA ITEM 4: ................................................................................................................................................108 PROPOSAL FOR RESOLUTION 63.............................................................................................................................108 PROPOSAL FOR RECOMMENDATION 719.................................................................................................................109 AGENDA ITEM 7.2: .............................................................................................................................................109 US_WRC_REV8.DOC 27.02.03 05.03.03 - 3 - USA Introduction In this document the United States makes proposals for many of the items on the WRC-03 agenda. The United States hopes that its proposals will serve to facilitate the development of consensus on these agenda items. The United States looks forward to working with the ITU membership to address these items that hold the potential for bringing benefits to governments, industries and consumers around the globe. The United States plans to supplement this document with some additional proposals, including some related to future Conferences, at a later date. The United States also notes its support for many of the Inter-American Proposals developed within the Inter-American Telecommunications Commission (CITEL). The United States will consider adoption of additional Inter-American Proposals as they are developed. United States Proposals Agenda Item 1.1: requests from administrations to delete their country footnotes or to have their country name deleted from footnotes, if no longer required, in accordance with Resolution 26 (Rev.WRC-97); Background Information: WRC-95 added footnote 5.389D to the Table of Allocations in the simplified Radio Regulations adopted by that Conference. Since the date specified in the footnote has come and gone, the United States is of the view that its name can be deleted from this provision in accordance with Resolution 26 (WRC-97). Proposal: ARTICLE 5 Frequency allocations MOD USA/ /1 5.389D In Canada and the United States the use of the bands 2 010-2 025 MHz and 2 160-2 170 MHz by the mobile-satellite service shall not commence before 1 January 2000. Reasons: Footnote is overcome by date and is no longer needed. Agenda Item 1.2: to review and take action, as required, on No. 5.134 and related Resolutions 517 (Rev.WRC-97) and 537 (WRC-97) and Recommendations 515 (Rev.WRC-97), 517 (HFBC-87), 519 (WARC-92) and Appendix 11, in the light of the studies and actions set out therein, having particular regard to the advancement of new modulation techniques, including digital techniques, capable of providing an US_WRC_REV8.DOC 27.02.03 05.03.03 - 4 - USA optimum balance between sound quality, bandwidth and circuit reliability in the use of the HF bands allocated to the broadcasting service. Background Information: This agenda item is directed towards the operational
Load more

Recommended publications
  • Chapter 22 Fundamentalfundamental Propertiesproperties Ofof Antennasantennas
    ChapterChapter 22 FundamentalFundamental PropertiesProperties ofof AntennasAntennas ECE 5318/6352 Antenna Engineering Dr. Stuart Long 1 .. IEEEIEEE StandardsStandards . Definition of Terms for Antennas . IEEE Standard 145-1983 . IEEE Transactions on Antennas and Propagation Vol. AP-31, No. 6, Part II, Nov. 1983 2 ..RadiationRadiation PatternPattern (or(or AntennaAntenna Pattern)Pattern) “The spatial distribution of a quantity which characterizes the electromagnetic field generated by an antenna.” 3 ..DistributionDistribution cancan bebe aa . Mathematical function . Graphical representation . Collection of experimental data points 4 ..QuantityQuantity plottedplotted cancan bebe aa . Power flux density W [W/m²] . Radiation intensity U [W/sr] . Field strength E [V/m] . Directivity D 5 . GraphGraph cancan bebe . Polar or rectangular 6 . GraphGraph cancan bebe . Amplitude field |E| or power |E|² patterns (in linear scale) (in dB) 7 ..GraphGraph cancan bebe . 2-dimensional or 3-D most usually several 2-D “cuts” in principle planes 8 .. RadiationRadiation patternpattern cancan bebe . Isotropic Equal radiation in all directions (not physically realizable, but valuable for comparison purposes) . Directional Radiates (or receives) more effectively in some directions than in others . Omni-directional nondirectional in azimuth, directional in elevation 9 ..PrinciplePrinciple patternspatterns . E-plane . H-plane Plane defined by H-field and Plane defined by E-field and direction of maximum direction of maximum radiation radiation (usually coincide with principle planes of the coordinate system) 10 Coordinate System Fig. 2.1 Coordinate system for antenna analysis. 11 ..RadiationRadiation patternpattern lobeslobes . Major lobe (main beam) in direction of maximum radiation (may be more than one) . Minor lobe - any lobe but a major one . Side lobe - lobe adjacent to major one .
    [Show full text]
  • 25. Antennas II
    25. Antennas II Radiation patterns Beyond the Hertzian dipole - superposition Directivity and antenna gain More complicated antennas Impedance matching Reminder: Hertzian dipole The Hertzian dipole is a linear d << antenna which is much shorter than the free-space wavelength: V(t) Far field: jk0 r j t 00Id e ˆ Er,, t j sin 4 r Radiation resistance: 2 d 2 RZ rad 3 0 2 where Z 000 377 is the impedance of free space. R Radiation efficiency: rad (typically is small because d << ) RRrad Ohmic Radiation patterns Antennas do not radiate power equally in all directions. For a linear dipole, no power is radiated along the antenna’s axis ( = 0). 222 2 I 00Idsin 0 ˆ 330 30 Sr, 22 32 cr 0 300 60 We’ve seen this picture before… 270 90 Such polar plots of far-field power vs. angle 240 120 210 150 are known as ‘radiation patterns’. 180 Note that this picture is only a 2D slice of a 3D pattern. E-plane pattern: the 2D slice displaying the plane which contains the electric field vectors. H-plane pattern: the 2D slice displaying the plane which contains the magnetic field vectors. Radiation patterns – Hertzian dipole z y E-plane radiation pattern y x 3D cutaway view H-plane radiation pattern Beyond the Hertzian dipole: longer antennas All of the results we’ve derived so far apply only in the situation where the antenna is short, i.e., d << . That assumption allowed us to say that the current in the antenna was independent of position along the antenna, depending only on time: I(t) = I0 cos(t) no z dependence! For longer antennas, this is no longer true.
    [Show full text]
  • Development of Earth Station Receiving Antenna and Digital Filter Design Analysis for C-Band VSAT
    INTERNATIONAL JOURNAL OF SCIENTIFIC & TECHNOLOGY RESEARCH VOLUME 3, ISSUE 6, JUNE 2014 ISSN 2277-8616 Development of Earth Station Receiving Antenna and Digital Filter Design Analysis for C-Band VSAT Su Mon Aye, Zaw Min Naing, Chaw Myat New, Hla Myo Tun Abstract: This paper describes the performance improvement of C-band VSAT receiving antenna. In this work, the gain and efficiency of C-band VSAT have been evaluated and then the reflector design is developed with the help of ICARA and MATLAB environment. The proposed design meets the good result of antenna gain and efficiency. The typical gain of prime focus parabolic reflector antenna is 30 dB to 40dB. And the efficiency is 60% to 80% with the good antenna design. By comparing with the typical values, the proposed C-band VSAT antenna design is well optimized with gain of 38dB and efficiency of 78%. In this paper, the better design with compromise gain performance of VSAT receiving parabolic antenna using ICARA software tool and the calculation of C-band downlink path loss is also described. The particular prime focus parabolic reflector antenna is applied for this application and gain of antenna, radiation pattern with far field, near field and the optimized antenna efficiency is also developed. The objective of this paper is to design the downlink receiving antenna of VSAT satellite ground segment with excellent gain and overall antenna efficiency. The filter design analysis is base on Kaiser window method and the simulation results are also presented in this paper. Index Terms: prime focus parabolic reflector antenna, satellite, efficiency, gain, path loss, VSAT.
    [Show full text]
  • Methods for Measuring Rf Radiation Properties of Small Antennas
    Helsinki University of Technology Radio Laboratory Publications Teknillisen korkeakoulun Radiolaboratorion julkaisuja Espoo, October, 2001 REPORT S 250 METHODS FOR MEASURING RF RADIATION PROPERTIES OF SMALL ANTENNAS Clemens Icheln Dissertation for the degree of Doctor of Science in Technology to be presented with due permission for public examination and debate in Auditorium S4 at Helsinki University of Technology (Espoo, Finland) on the 16th of November 2001 at 12 o'clock noon. Helsinki University of Technology Department of Electrical and Communications Engineering Radio Laboratory Teknillinen korkeakoulu Sähkö- ja tietoliikennetekniikan osasto Radiolaboratorio Distribution: Helsinki University of Technology Radio Laboratory P.O. Box 3000 FIN-02015 HUT Tel. +358-9-451 2252 Fax. +358-9-451 2152 © Clemens Icheln and Helsinki University of Technology Radio Laboratory ISBN 951-22- 5666-5 ISSN 1456-3835 Otamedia Oy Espoo 2001 2 Preface The work on which this thesis is based was carried out at the Institute of Digital Communications / Radio Laboratory of Helsinki University of Technology. It has been mainly funded by TEKES and the Academy of Finland. I also received financial support from the Wihuri foundation, from HPY:n Tutkimussäätiö, from Tekniikan Edistämissäätiö, and from Nordisk Forskerutdanningsakademi. I would like to thank all these institutions, and the Radio Laboratory, for making this work possible for me. I am especially thankful for the many ideas and helpful guidance that I got from my supervisor professor Pertti Vainikainen during all my work. Of course I would also like to thank the staff of the Radio Laboratory, who provided a pleasant and inspiring working atmosphere, in which I got lots of help from my colleagues - let me mention especially Stina, Tommi, Jani, Lorenz, Eino and Lauri - without whom this work would not have been possible.
    [Show full text]
  • Measurement Techniques and New Technologies for Satellite Monitoring
    Report ITU-R SM.2424-0 (06/2018) Measurement techniques and new technologies for satellite monitoring SM Series Spectrum management ii Rep. ITU-R SM.2424-0 Foreword The role of the Radiocommunication Sector is to ensure the rational, equitable, efficient and economical use of the radio- frequency spectrum by all radiocommunication services, including satellite services, and carry out studies without limit of frequency range on the basis of which Recommendations are adopted. The regulatory and policy functions of the Radiocommunication Sector are performed by World and Regional Radiocommunication Conferences and Radiocommunication Assemblies supported by Study Groups. Policy on Intellectual Property Right (IPR) ITU-R policy on IPR is described in the Common Patent Policy for ITU-T/ITU-R/ISO/IEC referenced in Annex 1 of Resolution ITU-R 1. Forms to be used for the submission of patent statements and licensing declarations by patent holders are available from http://www.itu.int/ITU-R/go/patents/en where the Guidelines for Implementation of the Common Patent Policy for ITU-T/ITU-R/ISO/IEC and the ITU-R patent information database can also be found. Series of ITU-R Reports (Also available online at http://www.itu.int/publ/R-REP/en) Series Title BO Satellite delivery BR Recording for production, archival and play-out; film for television BS Broadcasting service (sound) BT Broadcasting service (television) F Fixed service M Mobile, radiodetermination, amateur and related satellite services P Radiowave propagation RA Radio astronomy RS Remote sensing systems S Fixed-satellite service SA Space applications and meteorology SF Frequency sharing and coordination between fixed-satellite and fixed service systems SM Spectrum management Note: This ITU-R Report was approved in English by the Study Group under the procedure detailed in Resolution ITU-R 1.
    [Show full text]
  • A Novel Method of Beamforming to Improve the Space Diversity
    A Novel Method of Beamforming to Improve the Space Diversity Marco Antonio Acevedo Mosqueda, Emmanuel Martínez Zavala, María Elena Acevedo Mosqueda, and Oleksiy Pogrebnyak Abstract —At present, the systems of mobile communications The method to increase secondary lobes is described in demand major capacity in the services, therefore optimum space Section IV and finally, Section V presents different diversity is needed. In this paper, we propose a new method of simulations to obtain a radiation pattern by increasing the beam-forming to improve the space diversity and achieve magnitude of side lobes, which is comparable to the radiation frequency reuse. Our proposal consists in solving a system of pattern of Dolph-Chebyshev which has a polynomial order of linear equations from an 8-elements linear antenna array that increases the size of the side lobes. This method is compared with m = 8 and a maximum ratio of 4 dB side lobes. the algorithm of Dolph-Chebyshev. Our method shows competitive results in increasing the space diversity. II. ARRAY FACTOR FOR LINEAR WEIGHTED UNIFORM SYMMETRICAL ARRAYS Index Terms —Beamforming, Space diversity, Linear antenna An antenna array is a set of simple antennas which are array, Dolph-Chebyshev. connected under certain conditions, and they are usually equal and oriented in the same direction. They are arranged in a I. INTRODUCTION specific physical layout and relatively close with respect to each other. The combination of all these parameters provides a N RECENT DECADES , the interest in the antenna array has unique radiation pattern with desirable features such as width grown significantly due to it plays an important role in of the main lobe, the location of zero and maximum angles, mobile communications systems.
    [Show full text]
  • Performance Evaluation of Array Antennas
    International Journal of Modern Engineering Research (IJMER) www.ijmer.com Vol.1, Issue.2, pp-510-515 ISSN: 2249-6645 PERFORMANCE EVALUATION OF ARRAY ANTENNAS K.Ch.sri Kavya1 , Y.N.Sandhya Devi2 ,G.Sudheer Kumar2 , Narendra Neupane2 1(Associate Professor, Dept. of Electronics and Communication Engineering, KL University.) 2 PERFORMANCE(B.Tech Scholars, Dept. of EVALUATION Electronics and Communication OF Engineering, ARRAY KL University.) ANTENNAS ABSTRACT The purpose of the paper is to present a proper This paper will presents an optimization technique to reduce the side lobe level in the case normalization technique to obtain a low side lobe of linear array antennas. There several methods level and to avoid loss in main lobe directivity. are introduced for the side lobe reduction .But always the basic trade-off occur when II.METHODOLOGIES implementing amplitude weighting functions is that a trade between low side lobe levels and a loss A. Uniform Illumination method in main beam directivity always results . Here we Equal illumination at every element in an array made a comparison of three methods namely referred to as uniform illumination, results in uniform illumination method , Taylor line source directivity patterns with three distinct features. attenuation method and Taylor line source using Firstly, uniform illumination gives the highest redistribution method .The paper also presents aperture efficiency possible of 100% or 0 dB, for any different source distributions and their respective given aperture area. Secondly, the first side lobes for directivity patterns. a linear/rectangular aperture have peaks of approximately –13.1 dB relative to the main beam Keywords: Amplitude weighing, uniform peak; and the first side lobes for a circular aperture illumination, array antennas, normalization.
    [Show full text]
  • ANTENNA INTRODUCTION / BASICS Rules of Thumb
    ANTENNA INTRODUCTION / BASICS Rules of Thumb: 1. The Gain of an antenna with losses is given by: Where BW are the elev & az another is: 2 and N 4B0A 0 ' Efficiency beamwidths in degrees. G • Where For approximating an antenna pattern with: 2 A ' Physical aperture area ' X 0 8 G (1) A rectangle; X'41253,0 '0.7 ' BW BW typical 8 wavelength N 2 ' ' (2) An ellipsoid; X 52525,0typical 0.55 2. Gain of rectangular X-Band Aperture G = 1.4 LW Where: Length (L) and Width (W) are in cm 3. Gain of Circular X-Band Aperture 3 dB Beamwidth G = d20 Where: d = antenna diameter in cm 0 = aperture efficiency .5 power 4. Gain of an isotropic antenna radiating in a uniform spherical pattern is one (0 dB). .707 voltage 5. Antenna with a 20 degree beamwidth has a 20 dB gain. 6. 3 dB beamwidth is approximately equal to the angle from the peak of the power to Peak power Antenna the first null (see figure at right). to first null Radiation Pattern 708 7. Parabolic Antenna Beamwidth: BW ' d Where: BW = antenna beamwidth; 8 = wavelength; d = antenna diameter. The antenna equations which follow relate to Figure 1 as a typical antenna. In Figure 1, BWN is the azimuth beamwidth and BW2 is the elevation beamwidth. Beamwidth is normally measured at the half-power or -3 dB point of the main lobe unless otherwise specified. See Glossary. The gain or directivity of an antenna is the ratio of the radiation BWN BW2 intensity in a given direction to the radiation intensity averaged over Azimuth and Elevation Beamwidths all directions.
    [Show full text]
  • Beam Forming in Smart Antenna with Improved Gain and Suppressed Interference Using Genetic Algorithm
    Cent. Eur. J. Comp. Sci. • 2(1) • 2012 • 1-14 DOI: 10.2478/s13537-012-0001-0 Central European Journal of Computer Science Beam forming in smart antenna with improved gain and suppressed interference using genetic algorithm Research Article T. S. Ghouse Basha1∗, M. N. Giri Prasad2, P.V. Sridevi3 1 K.O.R.M.College of Engineering, Kadapa, Andhra Pradesh, India 2 J.N.T.U.College of Engineering, Anantapur, Andhra Pradesh, India 3 Department of ECE, AU College of Engineering, Andhra University, Visakha Patnam, Andhra Pradesh, India Received 21 September 2011; accepted 18 November 2011 Abstract: The most imperative process in smart antenna system is beam forming, which changes the beam pattern of an antenna for a particular angle. If the antenna does not change the position for the specified angle, then the signal loss will be very high. By considering the aforesaid drawback, here a new genetic algorithm based technique for beam forming in smart antenna system is proposed. In the proposed technique, if the angle is given as input, the maximum signal gain in the beam pattern of the antenna with corresponding position and phase angle is obtained as output. The length of the beam, interference, phase angle, and the number of patterns are the factors that are considered in our proposed technique. By using this technique, the gain of the system gets increased as well as the interference is reduced considerably. The implementation result exhibits the efficiency of the system in beam forming. Keywords: smart antenna • beam forming • genetic algorithm (GA) • phase angle • main beam © Versita Sp.
    [Show full text]
  • ECE 604, Lecture 27
    ECE 604, Lecture 27 Wed, Mar 27, 2019 Contents 1 Linear Array of Dipole Antennas 2 1.1 Far-Field Approximation . 2 1.2 Radiation Pattern of an Array . 3 2 When is Far-Field Approximation Valid? 6 2.1 Rayleigh Distance . 7 2.2 Near Zone, Fresnel Zone, and Far Zone . 8 Printed on March 28, 2019 at 23 : 12: W.C. Chew and D. Jiao. 1 ECE 604, Lecture 27 Wed, Mar 27, 2019 1 Linear Array of Dipole Antennas Antenna array can be designed so that the constructive and destructive inter- ference in the far field can be used to steer the direction of radiation of the antenna, or the far-field radiation pattern of an antenna array. A simple linear dipole array is shown in Figure 1. Figure 1: First, we assume that this is a linear array of Hertzian dipoles aligned on the x axis. The current can then be described mathematically as follows: 0 0 0 0 J(r ) =zIl ^ [A0δ(x ) + A1δ(x − d1) + A2δ(x − d2) + ··· 0 0 0 + AN−1δ(x − dN−1)]δ(y )δ(z ) (1.1) 1.1 Far-Field Approximation The vector potential on the xy-plane in the far field is derived to be µIl 0 A(r) =∼ z^ e−jβr dr0[A δ(x0) + A δ(x0 − d ) + ··· ]δ(y0)δ(z0)ejβr ·r^ 4πr ˚ 0 1 1 µIl =z ^ e−jβr[A + A ejβd1 cos φ + A ejβd2 cos φ + ··· + A ejβdN−1 cos φ] 4πr 0 1 2 N−1 (1.2) In the above, we have assumed that the observation point is on the xy plane, or that r = ρ =xx ^ +yy ^ .
    [Show full text]
  • Wireless Side-Lobe Eavesdropping Attacks
    Wireless Side-Lobe Eavesdropping Attacks Yanzi Zhu, Ying Ju§†, Bolun Wang, Jenna Cryan‡, Ben Y. Zhao‡, Haitao Zheng‡ University of California, Santa Barbara §Xi’an Jiaotong University †State Radio Monitoring Center ‡University of Chicago {yanzi, bolunwang}@cs.ucsb.edu, [email protected], {jennacryan, ravenben, htzheng}@cs.uchicago.edu ABSTRACT cation. Many such applications have already been deployed. Facebook has deployed a mesh network using 60GHz com- Millimeter-wave wireless networks offer high throughput and munications in downtown San Jose [7]. Google is consider- can (ideally) prevent eavesdropping attacks using narrow, ing replacing wired fiber with mmWave to reduce cost [5]. directional beams. Unfortunately, imperfections in physi- Academics have proposed picocell networks using mmWave cal hardware mean today’s antenna arrays all exhibit side signals towards next 5G network [29, 32, 42]. lobes, signals that carry the same sensitive data as the main With a growing number of deployed networks and ap- lobe. Our work presents results of the first experimental plications, understanding physical properties of mmWave is study of the security properties of mmWave transmissions critical. One under-studied aspect of directional transmis- against side-lobe eavesdropping attacks. We show that these sions is the artifact of array side lobes. Fig. 1 shows an ex- attacks on mmWave links are highly effective in both indoor ample of the series of side lobes pointing in different direc- and outdoor settings, and they cannot be eliminated by im- tions. Side lobes are results of imperfect signal cancellation proved hardware or currently proposed defenses. among antenna elements. While weaker than the main lobe, 1.
    [Show full text]
  • Stadium(Wi*Fi(Deployments
    Stadium(Wi*Fi(Deployments Mike%Leibovitz,%Director%of%Mobility%and%Applica8ons,%Extreme%Networks% Reaching New Heights ! Extreme Networks is the #1 provider of stadium-class high density Wi-Fi ! Extreme is the official Wi-Fi analytics provider of the NFL ! Extreme delivers robust connectivity with fewer access points ©2014 Extreme Networks, Inc. All rights reserved. Experience Driven ! Stadium Wi-Fi is not about technology; its about fan experience ! Wi-Fi enables new experiences for fans – its an incursion ! You can’t build when the fan asks for it ! Failure is costly – worse than having no Wi-Fi? bad Wi-Fi! ©2014 Extreme Networks, Inc. All rights reserved. Why So Challenging? ! 70,000+ people in the building ! You cannot recreate the scenario in an empty stadium ! No two stadiums are identical ! Same IT expectations – small shops – holistic visibility, reliability, control are crucial ©2014 Extreme Networks, Inc. All rights reserved. Solving Scale Is More Than RF ! Wired infrastructure: Access-to-Datacenter ! Context-aware provisioning, analytics, and reporting ! Command and control management system ©2014 Extreme Networks, Inc. All rights reserved. Physical Challenges ! Sheer size of the project is daunting ! Miles of cabling, IDF/MDF considerations – PoE ! Type of expected weather conditions ! Sight lines and aesthetics ! There are always unknown factors you can’t account for ©2014 Extreme Networks, Inc. All rights reserved. Wi-Fi Challenges RF signal travels far in free space ! Many devices – elevated noise floor ! Some running hotspots ! Mostly 1x1 clients ! Frequency scarcity ! 2.4Ghz is nice to have, 5Ghz is critical ! Often using 2x 5Ghz radios in an area ! We typically see about 60% of devices on the 5Ghz spectrum ! Seeing about 30% of Androids with 802.11ac support ! Distances of some clients, in long sections ©2014 Extreme Networks, Inc.
    [Show full text]