Download presentation
Presentation is loading. Please wait.
Published byLaureen Stevenson Modified over 9 years ago
1
www.gvf.org The $20 Billion Question: Can Satellite and Terrestrial Wireless Co-Exist in C-band? David Hartshorn Secretary General GVF
2
www.gvf.org Why Is SatCom Important in C-band?
3
www.gvf.org Spectrum : –ITU table of allocations allows FSS only in selected bands –Bandwidth requirements for traditional FSS applications need to be met in the selected band –Civilian Use Industry Supply, User Demand: –Many satellites available –Well established, increasingly inexpensive technology –Widely used for a multitude of satellite services like: TV broadcast to cable networks TV broadcast to individual receivers VSAT networks Internet providers Point-to-multipoint links Satellite News Gathering MSS feeder links Why Is Satcom Operating in C-band?
4
www.gvf.org Newcomers in C-band downlinks Band commonly used by FSS satellites Additional band (FSS, feederlinks for MSS, …) Future mobile phone networks (IMT Advanced, 4G, ….) Broadband Wireless Access (BWA), WiMax, FWA, …. Is being considered by ITU Is currently being introduced country by country worldwide BWA or IMT in ANY part of satcom C-band downlink will have an impact on FSS reception in ALL of the band 3.43.53.63.73.83.9 4.0 4.14.2 Std. C Etx. C
5
www.gvf.org Impact on FSS Reception In-band interference Interference from unwanted emissions (outside the signal bandwidth) Overdrive of LNB’s Exclusion zones around earth stations are required if these terrestrial wireless services are to operate in the band
6
www.gvf.org Exclusion Zones: A Viable Solution? Example of calculated exclusion zone around an earth station to counter interference from a single IMT base station in each cell (From French study to ITU Working Party 8F (Document WP 8F/868))
7
www.gvf.org Exclusion zone Example of exclusion zone with a radius of 20 km around an earth station in Singapore
8
www.gvf.org USE OF 3625 – 4200 MHz BY THE FSS IN BRAZIL Brazilian Contribution at June CITEL Meeting (OEA/Ser.L/XVII.4.2 CCP.II-RADIO/doc. 974/06): No Better Band to Address Rain Attenuation Exclusion Zones Unworkable in Nations with High-Density Satcom Deployment Developing Countries Can’t Afford Equipment Changeout Conclusion: 3625-4200 & 4500 – 4800 MHz Should Not Be Considered for IMT
9
www.gvf.org Exclusion zones May be enforced for base stations with respect to specific earth stations Cannot be applied with respect to user terminals Will require user terminals which do not emit any signals when they are not in contact with a base station Cannot be applied with respect to unlicensed earth stations or earth stations at unknown locations Exclusion zones around earth stations may block large areas for BWA or IMT and prohibit effective and economically viable operation
10
www.gvf.org In-band interference Example of calculated exclusion zone around an earth station to counter interference from a single IMT base station (From AsiaSat study to ITU Working Party 4A (Document WP 4A/304))
11
www.gvf.org Unwanted emissions BWA band Signals appear at the input of the LNB with a much higher power density than the satellite signals How much suppresion of out-of-band components can one realistically expect from BWA or IMT equipment? Appendix 3 of the Radio Regulations provide limits for spurious emissions
12
www.gvf.org Example of calculated exclusion zone around an earth station to counter spurious emissions in accordance with the levels prescribed by Appendix 3 of the Radio Regulations (From AsiaSat study to ITU Working Party 4A (Document WP 4A/304)) Unwanted emissions
13
www.gvf.org Overdrive of LNB BWA band BWA or IMT signals can produce much higher powers than the satellite signals at the LNB input and can thus overdrive the LNB or bring it into non-linear operation Normal LNB bandwidth X LO LNA LNB
14
www.gvf.org Distortion of received FSS spectre by BWA signal Overdrive of LNB Intermodulation products BWA carrier 3.3 GHz 4.3 GHz
15
www.gvf.org Overdrive of LNB 1. BWA signal off 3. BWA EIRP 1.6 W 2. BWA EIRP 0.5 W4. BWA EIRP 5 W Example of gain compression and intermodulation of LNB by single BWA base station (BWA signal at 3.505 GHz (bandwidth 3.5 MHz), spectrum plots 3.775-3.675 GHz)
16
www.gvf.org Overdrive of LNB Example of calculated exclusion zone around an earth station to avoid overdrive or non-linear operation of the LNB (From AsiaSat study to ITU Working Party 4A (Document WP 4A/304))
17
www.gvf.org RF waveguide bandpass filter Only helps against overdrive of LNB Cannot mitigate in-band interference Cannot mitigate unwanted emissions Only provides limited reduction of overdrive effects For many antennas, in particular receive only antennas, LNB and antenna feedhorn are molded together in one unit and no filter can be inserted in between Expensive (~ USD 1000.-). Inserting such in all receive installations becomes a significant cost X LO LNA LNB Antenna feedhorn Waveguide BP filter Waweguide flanges
18
www.gvf.org Conclusions BWA or IMT in a part or all of the FSS C-band downlink will be incompatible with general FSS reception in any part of C-band in the same geographical area BWA or IMT in a part of C-band may be compatible with FSS reception by a small number of earth stations if: –Appropriate exclusion zones around each of the earth stations are established –User terminals are designed not to emit any signals when not in contact with a base station Introduction of BWA or IMT by one country can block FSS reception in another country
19
www.gvf.org Alternative frequency bands S-band (e.g. 2.29 – 2.4835 GHz) 7 GHz band Spectrum refarming FSS uplink bands (frequencies > 6.425 GHz less used)
Similar presentations
© 2024 SlidePlayer.com Inc.
All rights reserved.