D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 1 November 2004 doc.: IEEE a Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: M-ary Code Shift Keying/Binary PPM (MCSK/BPPM) Based Impulse Radio Date Submitted: November 22, 2004 Source: [Dong In Kim (1), Serhat Erküçük (1), Kyung Sup Kwak (2)] Company: [(1) Simon Fraser University (2) UWB-ITRC, Inha University] Address: [(1) School of Engineering Science, 8888 University Drive, Burnaby, BC V5A 1S6, Canada (2) 253 Yonghyun-Dong, Nam-Gu, #401, Venture Bldg. Incheon, Korea] Voice: [+1 (604) ], Fax: [(1) +1 (604) (2) ] [(1) (2) Abstract: [This document proposes preliminary proposal for the IEEE alternate PHY standard] Purpose: [Preliminary Proposal for the IEEE a standard] Notice: This document has been prepared to assist the IEEE P It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein. Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P802.15

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 2 November 2004 doc.: IEEE a Preliminary Proposal for IEEE a Alternate PHY M-ary Code Shift Keying/Binary PPM (MCSK/BPPM) Based Impulse Radio SFU, Canada & UWB-ITRC, Inha University Republic of Korea

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 3 November 2004 doc.: IEEE a Contents TG4a Requirements MCSK/BPPM PHY TX Structure TH Code Assignment Transceiver Architecture Information Rate Location Accuracy Conclusion

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 4 November 2004 doc.: IEEE a TG4a Requirements a PHY MCSK/BPPM compared to TH-PPM scalable information rates Better BER performance at the same/higher information rates and lower transmit power high precision ranging/ location Improved ranging/location precision capability low power consumption Lower transmit power at the same/higher information rates and better BER performance low complexity and cost No new circuit is needed / simple transceiver structure *MCSK/BPPM: M-ary Code Shift Keying/Binary Pulse Position Modulation **TH-PPM: Time Hopping Pulse Position Modulation

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 5 November 2004 doc.: IEEE a MCSK/BPPM TH PPM – user #1 MCSK/BPPM – user #1 1 user specific TH code TH-BPPM 0 t 1101 M user specific TH codes TH-BPPM choose a code 1 TH code … M=4 c3c3 TX only for multiple access for multiple access and data modulation MCSK: M-ary Code Shift Keying BPPM: Binary Pulse Position Modulation 0 t Bit time Frame time

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 6 November 2004 doc.: IEEE a M user specific TH codes - TH codes are periodic with N p - each pulse should be repeated N s times - N p /N s =k is an integer Example: 0 t C 2  PHY TX Structure (1/2) MCSK BPPM TX Bit time Frame time

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 7 November 2004 doc.: IEEE a PHY TX Structure (2/2) M user specific TH codes - TH codes are periodic with N p - each pulse should be repeated N s times - N p /N s =k is an integer Information rate vs. BER performance for fixed N s and varying N p and M ScenarioTime domain illustration Info. rate BER performance 1 bit (BPPM) 2 bits (MCSK) 1 bit (BPPM) 3 bits (MCSK) 1 bit (BPPM) 3 bits (MCSK) 1 bit (BPPM) N p /N s same M increasing N p /N s increasing M same TX Bit time Frame time

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 8 November 2004 doc.: IEEE a M user specific TH codes Each user has sample-long sequence ? NO! Generation of TH codes – “Case 1: random assignment” m-sequence: 0 For T f = 100ns, T c = 1ns: 100 slots for multiple access c0c0 c1c1 c2c2 c3c3 user #1 c0c0 c1c1 c2c2 c3c3 user #2 TH Code Assignment (1/2) TX

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 9 November 2004 doc.: IEEE a TH Code Assignment (2/2) user #2 Generation of TH codes – “Case 2: no overlapping” user #1 user #2user #k... user #1 no collisions allowed within user codes n: number of overlaps TX

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 10 November 2004 doc.: IEEE a General Modulation Format Extra information Random selection of TH codes  Smooth spectrum Fixed signal space Increased information rate TX

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 11 November 2004 doc.: IEEE a Receiver Structure - MLSE M N p /N s computation complexity template signals 2M2M M hardware structure correlators RX

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 12 November 2004 doc.: IEEE a Information Rate (1/2) TH-BPPM Ns = 2, M=1 MCSK/BPPM “Constant Energy/Bit” Constraint Ns = 2, Np=2, M=2 MCSK/BPPM “Constant Power” Constraint Ns = 2, Np=2, M=2 MCSK/BPPM (same info. rate) “Constant Power” Constraint Ns = 2, Np=2, M=2 A A A’ Info. rate R s R 2R R can be adjusted to achieve higher information rate at lower transmit power and still maintain better BER performance at the same time

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 13 November 2004 doc.: IEEE a Information Rate (2/2) Scalable info. rates 0 A’=2A 0 A 0 A’=1.58A 0 A 0 A’=1.41A 0 A MCSK/BPPM “Constant Power” Constraint for N s = 1, M=8 4R  R 2.5R  R 2R  R BER performance (wrt TH-PPM) - same collusion effects - no processing gain - no improvement - same collusion effects - processing gain - improved BER - TX power can be lowered - info rate can be increased

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 14 November 2004 doc.: IEEE a Location Accuracy ProcedureResultComment Step 0 Step 1 Step 3 Step 2 Step 4 Increase M Increase N p /N s Increase T’ f Increase A’ Initial conditions for TH-PPM R 0 (information rate); BER 0 (performance) TX 0 (power) BER 2 may or may not be less than BER 0 BER 3 may or may not be less than BER 0 Increased frame time with longer observation period, higher information rate, better BER performance and lower transmit power Accurate Ranging/Location MCSK/BPPM “Constant Power” Constraint

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 15 November 2004 doc.: IEEE a Conclusion MCSK/BPPM provides:  increased information rate  lower transmit power  better BER performance  improved spectral characteristics MCSK/BPPM is capable of:  information rate scalability  location/ranging accuracy Simultaneously! IEEE a PHY

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 16 November 2004 doc.: IEEE a Back-up Slides

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 17 November 2004 doc.: IEEE a MCSK/BPPM “Constant Energy/Bit” Constraint

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 18 November 2004 doc.: IEEE a MCSK/BPPM “Constant Power” Constraint

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 19 November 2004 doc.: IEEE a MCSK/BPPM “Constant Power” Constraint  Improved performance at the same information rate for M=8

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 20 November 2004 doc.: IEEE a Effects of TH Code Design on the Performance MCSK/BPPM “Constant Power” Constraint

D. I. Kim, S. Erküçük, K. S. Kwak Submission Slide 21 November 2004 doc.: IEEE a TH Code Spectrum of: a)TH-BPPM, N p =10 b)ideal MCSK/BPPM, N p  c)realistic MCSK/BPPM Fig. b. ideal MCSK/BPPMFig. c. realistic MCSK/BPPM Fig. a. TH-BPPM