Presentation is loading. Please wait.

Presentation is loading. Please wait.

Scrambler Mismatch and MAC FEC: Is there a problem?

Published byJasmine McCann Modified over 10 years ago

Similar presentations

Presentation on theme: "Scrambler Mismatch and MAC FEC: Is there a problem?"— Presentation transcript:

1 Scrambler Mismatch and MAC FEC: Is there a problem?
September 2002 doc.: IEEE /636r0 September 2002 Scrambler Mismatch and MAC FEC: Is there a problem? Monisha Ghosh, Vasanth Gaddam Philips Research. Monisha Gosh et. al. Philips Monisha Gosh et. al. Philips

2 September 2002 Problem Statement The first 7 bits of the service field carry the scrambler initialization information. This field is not RS encoded in the MAC. A single bit error in this 7-bit sequence can cause the entire packet to be in error, since it is not RS encoded. Hypothesis: this will limit the effectiveness of the MAC FEC. Monisha Gosh et. al. Philips

3 Past Results/Solutions
September 2002 Past Results/Solutions Assuming the bit error rate (BER) to be uniform over the bit stream, it has been shown by analysis that a scrambler error can limit the MAC FEC performance. The analysis assumed AWGN only. Multipath can cause error bursts that will limit the efficacy of the MAC FEC independent of scrambler errors. Solutions proposed: dual precoding (can cause error propagation), extra bytes (increased overhead). Monisha Gosh et. al. Philips

4 September 2002 BER of a trellis code The 7-bit sequence containing the scrambler initialization is at the start of the bit sequence to be encoded. The trellis at that point is not “fully connected”, i.e. there is only a single path entering each state for the first 6 trellis transitions. The analytical expression for BER of a trellis code considers a fully connected trellis. Monisha Gosh et. al. Philips

5 September 2002 Hypothesis The BER for the first 7 bits of the trellis is lower than elsewhere in the trellis. The analytical results presented to date do not take this into effect. Simulation results indicate that indeed there is about an order of magnitude difference between the error rate of the scrambler initialization (7 bits) and bytes elsewhere in the data stream. Monisha Gosh et. al. Philips

6 September 2002 Simulation Results: 54 Mbps, 1616 bytes/packet, 5000 packets, AWGN Channel Monisha Gosh et. al. Philips

7 September 2002 Simulation Results: 54 Mbps, 496 bytes/packet, packets, AWGN + Multipath Channel Even though the byte error rate is higher when there is a scrambler initialization error, the packet error rate is not. This means that when there is an error in the scrambler initialization field, there are also errors in the rest of the data packet Monisha Gosh et. al. Philips

8 September 2002 Simulation Results Comparing Scrambler Initialization Error Rate with Byte Error Rate 54 Mbps, 50 byte packets, Multipath + AWGN channel, 1 million packets, SNR = 28 dB. The size of packets was reduced to make the simulation run faster. Byte Error Rate, assuming perfect initialization: 2.12e-05 Scrambler Error rate: 2.0e-06 25 byte packets, 4 million packets, SNR = 29 dB, Byte Error Rate = 5.38e-06, Scrambler error rate = 7.5e-07. Monisha Gosh et. al. Philips

9 September 2002 Conclusions The position of the 7-bit initialization sequence at the beginning of the trellis gives it added protection not accounted for in the analysis. Simulation results corroborate the above hypothesis: no discernable effect of scrambler error on packet error rate was noticed especially at higher SNRs. Simulation results indicate approximately an order of magnitude difference in the error rates of the scrambler initialization field versus the byte error rate. The MAC FEC gives a gain of about 2 dB. The limitation seems to be more from the lack of interleaving than from scrambler initialization errors. Monisha Gosh et. al. Philips

Download ppt "Scrambler Mismatch and MAC FEC: Is there a problem?"

Similar presentations

Doc.: IEEE 802.11-01/037 Submission January 2001 Khaled Turki et. al,Texas InstrumentsSlide 1 Simulation Results for p-DCF, v-DCF and Legacy DCF Khaled.

Doc.: IEEE /037 Submission January 2001 Khaled Turki et. al,Texas InstrumentsSlide 1 Simulation Results for p-DCF, v-DCF and Legacy DCF Khaled.
Doc: IEEE 802.11-02/705ar0 Submission Javier del Prado et. al November 2002 Slide 1 Mandatory TSPEC Parameters and Reference Design of a Simple Scheduler.

Doc: IEEE /705ar0 Submission Javier del Prado et. al November 2002 Slide 1 Mandatory TSPEC Parameters and Reference Design of a Simple Scheduler.
Doc.: IEEE 802.11-03/567r0 Submission May 2003 Youngsoo Kim, Samsung/SNU and S. Choi, SNU Slide 1 Throughput Enhancement via Frame Aggregation – A Sequel.

Doc.: IEEE /567r0 Submission May 2003 Youngsoo Kim, Samsung/SNU and S. Choi, SNU Slide 1 Throughput Enhancement via Frame Aggregation – A Sequel.
Doc.: IEEE 802.11-03/567r1 Submission July 2003 Youngsoo Kim, Samsung/SNU and S. Choi, SNU Slide 1 Throughput Enhancement via Frame Aggregation – A Sequel.

Doc.: IEEE /567r1 Submission July 2003 Youngsoo Kim, Samsung/SNU and S. Choi, SNU Slide 1 Throughput Enhancement via Frame Aggregation – A Sequel.
Doc.: IEEE 802.11-10/0527r0 Submission March 2010 Slide 1 A Periodic 5 MHz Measurement Pilot for Channel Scan Date: 2010-05-11 Authors:

Doc.: IEEE /0527r0 Submission March 2010 Slide 1 A Periodic 5 MHz Measurement Pilot for Channel Scan Date: Authors:
March 2002doc.: IEEE 802.11-02/221r0 Slide 1Submission Chris Heegard, TI Texas Instruments 141 Stony Circle, Suite 130 Santa Rosa California 95401 (707)

March 2002doc.: IEEE /221r0 Slide 1Submission Chris Heegard, TI Texas Instruments 141 Stony Circle, Suite 130 Santa Rosa California (707)
Doc.: IEEE 802.11-09/0237r0 Submission February 12, 2009 Rolf de Vegt (Qualcomm)Slide 1 Inputs for a 802.11ac Spec Framework Methodology Date: 2009-02-12.

Doc.: IEEE /0237r0 Submission February 12, 2009 Rolf de Vegt (Qualcomm)Slide 1 Inputs for a ac Spec Framework Methodology Date:
Doc.: IEEE 802.11-00/383 Submission November 2000 Yasuo Harada, Matushita Electric Slide 1 A consideration on FEC Bit error Performance of concatenation.

Doc.: IEEE /383 Submission November 2000 Yasuo Harada, Matushita Electric Slide 1 A consideration on FEC Bit error Performance of concatenation.
Doc.: IEEE 802.11-02/320r0 Submission May 2002 Gerhard Fettweis, Systemonic AGSlide 1 ¼ Giga-Bit/s WLAN Gerhard Fettweis Gunnar Nitsche Systemonic AG.

Doc.: IEEE /320r0 Submission May 2002 Gerhard Fettweis, Systemonic AGSlide 1 ¼ Giga-Bit/s WLAN Gerhard Fettweis Gunnar Nitsche Systemonic AG.
Doc.: IEEE 802.15-02/383 SG3a Submission Marcus Pendergrass Time Domain Corporation (TDC) September 2002 Project: IEEE P802.15 Working Group for Wireless.

Doc.: IEEE /383 SG3a Submission Marcus Pendergrass Time Domain Corporation (TDC) September 2002 Project: IEEE P Working Group for Wireless.
Doc.:IEEE 802.11-10/1275r0 Submission Laurent Cariou Nov, 2010 Slide 1 Complexity reduction for time domain H matrix feedback Authors: Date: 2010-11-09.

Doc.:IEEE /1275r0 Submission Laurent Cariou Nov, 2010 Slide 1 Complexity reduction for time domain H matrix feedback Authors: Date:
Doc.: IEEE 802.11-10/0534r1 Submission Duration in L-SIG Date: 2010-05-17 Youhan Kim, et al.Slide 1 Authors: May 2010.

Doc.: IEEE /0534r1 Submission Duration in L-SIG Date: Youhan Kim, et al.Slide 1 Authors: May 2010.
Doc.: IEEE 802.11-06/0909r0 Submission July 2006 David Tung, RalinkSlide 1 On L-SIG TXOP Protection Notice: This document has been prepared to assist IEEE.

Doc.: IEEE /0909r0 Submission July 2006 David Tung, RalinkSlide 1 On L-SIG TXOP Protection Notice: This document has been prepared to assist IEEE.
Doc.: IEEE 802.11-10/1290r0 Submission November 2010 Allert van Zelst, QualcommSlide 1 VHT-SIG-B in NDPs Date: 2010-11-02 Authors:

Doc.: IEEE /1290r0 Submission November 2010 Allert van Zelst, QualcommSlide 1 VHT-SIG-B in NDPs Date: Authors:
Doc.: IEEE 802.22-08/0104r0 Submission March 2008 Stephen Kuffner, MotorolaSlide 1 IEEE 802.22.1 Packet Error Rates for MSF1 and MSF2 IEEE P802.22 Wireless.

Doc.: IEEE /0104r0 Submission March 2008 Stephen Kuffner, MotorolaSlide 1 IEEE Packet Error Rates for MSF1 and MSF2 IEEE P Wireless.
Doc.: IEEE 802.22-07/0365r0 Submission July 2007 Monisha Ghosh, PhilipsSlide 1 Rate ¼ Convolution Code IEEE P802.22 Wireless RANs Date: 2007-07-17 Authors:

Doc.: IEEE /0365r0 Submission July 2007 Monisha Ghosh, PhilipsSlide 1 Rate ¼ Convolution Code IEEE P Wireless RANs Date: Authors:
Doc.: IEEE 802.19-05/0043r0 Submission November 2005 Steve Shellhammer, Qualcomm Inc.Slide 1 A Method of Curve Fitting to BER Data Notice: This document.

Doc.: IEEE /0043r0 Submission November 2005 Steve Shellhammer, Qualcomm Inc.Slide 1 A Method of Curve Fitting to BER Data Notice: This document.
PHY Abstraction for TGax System Level Simulations

PHY Abstraction for TGax System Level Simulations
Doc.: IEEE 802.11-02/380r0 Submission May 2002 Duncan Kitchin, IntelSlide 1 802.11 WG Assigned Numbers Authority Duncan Kitchin Intel Corporation.

Doc.: IEEE /380r0 Submission May 2002 Duncan Kitchin, IntelSlide WG Assigned Numbers Authority Duncan Kitchin Intel Corporation.
Doc.: IEEE 802.11-06/543r0 Submission April 2006 Richard van Nee, Airgo NetworksSlide 1 Transmitter CCA Issues in 2.4 GHz April 2006 06/543r0 Richard van.

Doc.: IEEE /543r0 Submission April 2006 Richard van Nee, Airgo NetworksSlide 1 Transmitter CCA Issues in 2.4 GHz April /543r0 Richard van.

Similar presentations

Ads by Google