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Doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 1 Improved Adjacent Channel Rejection Parameters to solve.

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Presentation on theme: "Doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 1 Improved Adjacent Channel Rejection Parameters to solve."— Presentation transcript:

1 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 1 Improved Adjacent Channel Rejection Parameters to solve the Near-Far Interference Problem Steve Brunson & Bob Soranno The Johns Hopkins University – Applied Physics Lab

2 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 2 Scenario of Interest Victim – A vehicle is parked in a gas station located on the corner of a major street. A large transaction is being performed on a short range link to an antenna under the canopy (~6m). (“Minimum” link power assumed) Interference – The roadway is 15 meters from the parked vehicle. Vehicles on the road may be conducting Traffic Probe transactions at 20 dBm and Vehicle-Vehicle transactions at 33 dBm in other channels.

3 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 3 The Near/Far Problem Near – Loud transmitter on a different channel (interference) “Far” – Distant or weak transmitter in tuned channel (desired signal) Interferer “Keep Out” Range Desired– 15 m Interference Power –Most transmitters will be 33 dBm or less

4 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 4 Mitigation Approaches Antenna Patterns –some help, but unfavorable geometries cannot be avoided Added IF filtering (SAW) – can be effective (40 dB beyond adjacent channel), but will increase cost (~$10?). Could be required for interference outside the DSRC band. Increased baseband filtering – effective, basis for Type 2 receiver Increased desired signal level – effective for short, low power links (-21 to -4 dBm required for 6 meter link with 0/0 dBi antennas)

5 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 5 Measure of Effectiveness Interferer “Keep-Out” Range – How close can you let an out-of-channel interferer get before you start losing packets? Inputs: –Level of Desired Signal (relative to MDS) –Level of Interference Rejection –Interference Power Transmitted –Antenna Patterns (0 dBi omni’s assumed) –Propagation (free space assumed) Interference independent of own xmt pwr.

6 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 6 Limiting Conditions Adjacent or Alternate Adjacent Channel Interference – leakage from strong signals in nearby channels Front End Saturation – nonlinear effects caused by strong signals in any other channel or out-of-band signals In general, Adjacent Channel problems seem more severe than Front End Saturation

7 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 7 Keep-Out Range Plots Keep-Out Range vs Received Power Received Power from MDS to MDS + 20 dB –One line for each data rate with applicable MDS and ACI-rejection (per Atheros) –Blue Lines: Interference Power = 20 dBm –Green Lines: Interference Power = 33 dBm –Both antennas 0 dBi –15 meter line in RED Faster Modes Lower because of poorer MDS –[mds: -85 -84 -82 -80 -77 -70 -69 -67 dBm]

8 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 8 Keep-Out Range: Type 2, Adj Chnl

9 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 9 Keep-Out Range: Type 1, Adj Chnl

10 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 10 Keep-Out Range: Type 1, Alt Adj Chnl

11 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 11 Conclusions Type 1 receivers will experience losses with 20 & 33 dBm adjacent channel interferers, BUT early deployment densities will be low. Type 2 receivers will be OK except for high power interferers (40 & 44.8 dBm), but these should be low density and/or transitory. Antenna Patterns will help the situation in most cases, especially high EIRP transmitters (these have narrow regions of max EIRP).

12 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 12 Back-up Slides

13 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 13 Keep-Out Range: Type 2, Alt Adj Chnl

14 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 14 Front End Saturation Saturation analysis based on information provided by Atheros Saturation can be caused by signals outside the DSRC band If out of band signals are a problem, a SAW filter in the IF may be required

15 doc.: IEEE 802.11-04/0143r0 Submission January 2004 Steve Brunson & Bob Soranno (JHU/APL)Slide 15 Saturation vs. ACI Max Gain Max Gain – 10 dB

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