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Physical Layer Model of the Impact of Bluetooth on IEEE 802.11b
July 2000 doc.: IEEE /220r0 July 2000 IEEE P Working Group for Wireless Personal Area NetworksTM Physical Layer Model of the Impact of Bluetooth on IEEE b Peter J. Voltz, Polytechnic University Peter J. Voltz, Polytechnic University
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Bluetooth interferer modeled as tone jammer
July 2000 doc.: IEEE /220r0 July 2000 Physical Layer Simulation Model For Impact of Bluetooth Interferer on 11Mbps Receiver Bluetooth interferer modeled as tone jammer Performance of Receiver depends on the following: Signal to Interference Ratio (SIR) Signal to Background Noise Ratio Frequency of Bluetooth Interferer Multipath Structure Receiver Processing Peter J. Voltz, Polytechnic University Peter J. Voltz, Polytechnic University
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Processing Options Basic Processing (BP) BP + MF
July 2000 Processing Options Basic Processing (BP) BP + MF Matched Filter (MF) for collecting multipath energy BP + MF + EQ Equalizer (EQ) to correct for Intersymbol Interference (ISI) Peter J. Voltz, Polytechnic University
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Tapped Delay Line Channel Model
July 2000 Tapped Delay Line Channel Model Channel Impulse Response Peter J. Voltz, Polytechnic University
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Pick Largest Pick Largest D-QPSK D-QPSK Channel Channel Matched Filter
July 2000 Channel Matched Filter Channel Pick Largest Pick Largest D-QPSK D-QPSK Peter J. Voltz, Polytechnic University
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Communication System Analysis
July 2000 Communication System Analysis Peter J. Voltz, Polytechnic University
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July 2000 Peter J. Voltz, Polytechnic University
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Output of Receiver due to 802.11 input
July 2000 Output of Receiver due to input Where Peter J. Voltz, Polytechnic University
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and the channel is clear, then and
July 2000 Note that if is time limited to Seconds, and the channel is clear, then and Which is the cross correlation between the receivers reference codeword and the particular codeword being received, times the phase factor which carries 2 bits. When a multipath channel is present, the non-zero values of for cause intersymbol interference. Peter J. Voltz, Polytechnic University
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Response to Interference
July 2000 Response to Interference Frequency offset, , has two effects Peter J. Voltz, Polytechnic University
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1. Effective amplitude of interferer is multiplied by
July 2000 1. Effective amplitude of interferer is multiplied by . 2. The discrete sine wave, , is correlated with the 64 CCK codewords and contributes to outputs. Peter J. Voltz, Polytechnic University
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July 2000 Simulation Results for three sample channels. Bluetooth Interferer at Band Center. Eb/No = 20 dB for white noise. Peter J. Voltz, Polytechnic University
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Effect of frequency offset due to digital sine wave correlation effect
July 2000 Effect of frequency offset due to digital sine wave correlation effect Peter J. Voltz, Polytechnic University
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Effect of frequency offset due to digital sine wave correlation effect
July 2000 Effect of frequency offset due to digital sine wave correlation effect Peter J. Voltz, Polytechnic University
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Effect of frequency offset due to digital sine wave correlation effect
July 2000 Effect of frequency offset due to digital sine wave correlation effect Peter J. Voltz, Polytechnic University
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July 2000 Conclusions We have modeled the b Receiver except for the Equalizer. Without the equalizer the effect of interference is heavily dependent on the actual channel model. At 10-4 the SIR varies from about 6 dB to about 18 dB Peter J. Voltz, Polytechnic University
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Next Steps Add the Equalizer into the model
July 2000 Next Steps Add the Equalizer into the model See if the variation due to the channel is reduced Develop a formula for the Symbol Error Rate (SER) as a function of SIR. Feed that (SER) formula into the MAC model. Peter J. Voltz, Polytechnic University
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