Towards ideal codes: looking for new turbo code schemes

1. Towards ideal codes: looking for new turbo code schemes Ph.D student: D. Kbaier Ben Ismail Supervisor: C. Douillard Co-supervisor: S. Kerouédan

2. What is a good code? • Ideal system • Limits to the correction capability of any code • Established by Shannon • Good convergence • Error rate greatly decreases close to the theoretical limit • Waterfall region • High asymptotic gain • Search for the ideal encoder/decoder pair • Dilemma: good convergence versus high MHD Ph.D defense, Monday 26th September 2011

3. Turbo codes http://www-elec.enst-bretagne.fr/demos/principe/turbo_codes.html Ph.D defense, Monday 26th September 2011

4. Constraints on λ Extract from my Ph.D report: Ph.D defense, Monday 26th September 2011

5. Choice of the post-encoder • Influences performance in both the waterfall and error floor region • Must be simple low memory RSC codes • The code is made tail biting  accumulator • Must not exhibit too much error amplification • EXIT analysis Ph.D defense, Monday 26th September 2011

6. Choice of the post-encoder k = 1146 bits R = 2/3 λ= 1/4 MAP, 10 iterations Ph.D defense, Monday 26th September 2011

7. Simulated performance of the 3D TC with random and regular interleavers Π’ • Regular permutation: • Achieves the maximum value of the spread • Performs better than the random interleaver k = 762 bits R = 1/2 λ= 1/8 Ph.D defense, Monday 26th September 2011 k = 762 bits k = 762 bits λ = 1/8

8. Performance of 3GPP2 based 3D TCs Ph.D defense, Monday 26th September 2011

9. Relation between λand dmin Extract from my Ph.D report pages 38-39: The authors in [63, 64] analyzed the asymptotic weight distribution of 3D TCs and showed that their typical minimum distance may, depending on certain parameters, asymptotically grow linearly with the block length. Ph.D defense, Monday 26th September 2011

10. Relation between λand dmin Ph.D defense, Monday 26th September 2011

11. 3D TCs hardware implementation issues:decoder architecture and complexity analysis • 3D turbo decoder architecture: • Input module • Double input buffer • Input buffer divided into as many MBs as P • Parallelism  different throughputs • Decoder module • P SISO processors & an extrinsic memory • Performs I iterations on the frame stored in the input module • Writes the decoded codeword into the output module • Output module • Stores the hard decisions produced by the decoder module • Sends them to the output of the decoder • No parallelism is considered for the predecoder • The predecoder has much less data to process than the main SISO decoders • Only λ = 1/4 or λ = 1/8 of the parity bits are reencoded Ph.D defense, Monday 26th September 2011

12. Main decoder module Extrinsic memory(syste-matic) MBP-1 MBP-1 MBP-1 SISO0 SISOP-1 SISO1 MB1 MB1 Input samples Decoded bits MB0 MB0 MB0 MB1 Input module Output module PREDEC SISO Extrinsic memory (parity) Pre-decoder module Typical overall 3D turbo decoder architecture Ph.D defense, Monday 26th September 2011

13. Max-Log-MAP decoder complexity analysis • Arithmetic and logical operations • Branch metrics • Forward and backward state metrics • Soft and hard decisions • Extrinsic information related to information bits • Extrinsic LLRs related to redundancy bits Ph.D defense, Monday 26th September 2011

14. Memory requirements for the 3D turbo decoder • The amount of RAM and ROM memory • TC permutation parameters  small amount of ROM memory • For the RAM memory: • 2 input buffers for each data sequence • Including systematic and parity bits • Stemming from the transmission channel • RAM to store the extrinsics • Additional extrinsics for the 3D TC • RAM to store the hardware decision at decoder output • Inside the SISO decoding process, state metrics have to be stored at each iteration Ph.D defense, Monday 26th September 2011

15. Optimization method Ph.D defense, Monday 26th September 2011

16. Optimization results for k = 1530 data bits k = 1530 R = 1/2 λ = 1/8 Before optimization After optimization Total increase in dmin by + 42 %  a gain of 2.5 decades in the error floor Max-Log-MAP, 10 iterations Ph.D defense, Monday 26th September 2011

17. Optimization results for k = 1146 data bits k = 1146 R = 2/3 λ = 1/4 • Ones concentrated in the systematic part at addresses {586, 587, 591, 650, 651,655, 763, 764, 768, 1019, 1020, 1024} Modification: {585, 587, 650, 651, 763 and 764} instead of {9, 101, 581, 925, 1029 and 1133} • The new minimum distance of the optimized 3D TC is 33 (compared to 7) Address 5 Address 13 Address 1 Address 9 Ph.D defense, Monday 26th September 2011

18. EXIT chart analysis: convergence threshold of the 3D TC EXIT chart based convergence analysis: • Determination of the convergence threshold of the TC & 3D TC (1.49 for an 8-state binary TC and R =2/3) • Compute the loss of convergence • Larger λ more significant loss EXIT chart of the 3D TC with λ = 1/8atEb/N0=1.5 dBfor code rate R = 2/3 EXIT chart of the 3D TC with λ = 1/8atEb/N0=1.55 dBfor code rate R = 2/3 Ph.D defense, Monday 26th September 2011

19. EXIT chart analysis: convergence threshold of the time varying 3D TC(1/2) R = 2/3 λ = 1/4 Eb/N0=1.57 dB Here Eb/N0 =1.57 dB < convergence threshold Ph.D defense, Monday 26th September 2011

20. EXIT chart analysis: convergence threshold of the time varying 3D TC(2/2) R = 2/3 λ = 1/4 Eb/N0=1.58 dB Convergence threshold:1.58 dB Ph.D defense, Monday 26th September 2011

21. Error rate performance of time varying 3D TCs • Time varying results for blocks of k = 1146 bits • Transmission over AWGN channel • Loss of convergence reduced by50% from 0:18 dB to 0:09 dB Ph.D defense, Monday 26th September 2011

22. An optimal value of L using EXIT charts? Ph.D defense, Monday 26th September 2011

23. An optimal value of L using EXIT charts? L=60 Eb/N0=1.6 dB Ph.D defense, Monday 26th September 2011

24. 3D TCs for high spectral efficiency transmissions • Transmission scheme • BICM approach • Among the bits forming a symbol in M-QAM or M-PSK modulations, the average probability of error is not the same for all the bits • Three constellation mappings: • Mapping uniformly distributed on the entire constellation • Systematic bits mapped to better protected places as a priority • Systematic bits (then if possible) post-encoded parity bits protected as a priority Ph.D defense, Monday 26th September 2011

25. Example: 3D TCs associated with an 8-PSK modulator 3 bits of an 8-PSK symbol 573 8-PSK symbols • The third configuration cannot be adopted • Systematic bits mapped to better protected places • Significant gain: 0.5 dB R = 4/5 λ = 1/8 k = 1146 bits 1146 x 143 y1 143 y2 288 w Ph.D defense, Monday 26th September 2011

26. Systematic part APP SISO Decoder Channel output Appropriate likelihoods repetition Π Product of Extrinsic information Decoding of irregular TCs • Only one SISO • The decoder computes the channel output LLRs • Appropriate repetition to each LLR • Aposteriori probability • Extrinsic information = product of d-1 extrinsics Ph.D defense, Monday 26th September 2011

27. Monte Carlo simulations • Fixing a degree dIrreg and varying its fraction fIrreg • A fraction that achieves the best performance can be found • Changing the degree dIrreg , while the fraction is fixed to the value already selected • We can then find optimal values for both dIrreg and fIrreg • This profile is not automatically the best one: • Optimization does not take into account all the possible combinations (dIrreg , fIrreg) • Better performance may be attained when the profile is not restricted to two non-zero fractions • Monte Carlo simulations are time consuming • We propose a method based on the EXIT diagrams to select a good degree profile Ph.D defense, Monday 26th September 2011

28. Determination of the degree profile using hierarchical EXIT charts • Plot the EXIT diagrams for a finite block length • Why? • For infinite block lengths • All the curves merge with one another •  We cannot distinguish between the different degree profiles • For finite block sizes • EXIT tool adapted • Hierarchy between the different degree profiles • Hypothesis: extrinsic information messages are i.i.d • The aim is not to compute accurate convergence thresholds • The method • Simple • Comparing many degree profiles at the same time • Even profiles with more than two non-zero fractions Ph.D defense, Monday 26th September 2011

29. Determination of the degree profile using hierarchical EXIT charts Ph.D defense, Monday 26th September 2011

30. Determination of the degree profile using hierarchical EXIT charts Ph.D defense, Monday 26th September 2011

31. Performance of irregular TCs • Irregular TCs can achieve performance closer to capacity • But very poor asymptotic performance • Only one reference [1] deals with the problem of lowering the error floor of irregular TCs • No previous work focused on optimizing the interleaver except in [2] • Our interest: • Not only large block lengths • But also medium and short blocks • Proposed solutions in [1,2] do not seem concrete • Especially if only few iterations are required during the decoding process [1] H. Sawaya and J. Boutros. “Irregular turbo-codes with symbol-based iterative decoding”, 3rd International Symposium on Turbo-codes, Brest, France, September 2003. [2] G. M. Kraidy and V. Savin, “Capacity-approaching irregular turbo codes for the binary erasure channel,” IEEE Trans. Com., vol. 58, no. 9, pp. 2516–2524, September 2010. Ph.D defense, Monday 26th September 2011

32. How to devise sophisticated permutations for irregular TCs? Example: Degree profile (f2,f8) f2 = 5/6 and f8 = 1/6 First idea: all the groups of 8 bits are uniformly distributed To avoid correlation  large spread between the pilot groups Empirical value for the spread: Constraint on f8: page 31 Ph.D defense, Monday 26th September 2011

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34. Performance of irregular TCs with post-encoding • All simulations use the MAP algorithm with 10 decoding iterations • Degree profile (f2,f8), dav = 3, R = ¼ and k = 2046 bits • 3GPP2 interleaver, interleaver size: 6138 Ph.D defense, Monday 26th September 2011