![6
Peak-to-Average Power Ratio of OFDM
For better approximation of the PAPR of continuous-time OFDM signals,
OFDM signal samples are obtained by L times oversampling.
L-times oversampled IFFT output can be expressed as 1
,
x [n] =
1
√
N
N−1
k=0
Xkej 2πnk
LN ; 0 ≤ n < LN − 1 (2)
PAPR of OFDM signal,
PAPR{x [n]} =
max0≤n≤NL |x [n] |2
E [|x [n] |2]
(3)
1T. Jiang and Y. Wu, ”An Overview: Peak-to-Average Power Ratio Reduction Techniques for OFDM Signals” in IEEE Transactions on
Broadcasting , vol. 54,no. 2,pp. 257–268 , 2008.
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![17
Scrambler and Descrambler
Figure: Scrambler for an N length sequence Figure: Descrambler for an N length sequence
These scramblers can be defined by the scrambler polynomial P where,
P = [ 1 P1 P2 ... PS] ; PS ∈ {1, 0} for s = 1..S
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papr-presentation
- 1. 1 High PAPR Sequence Scrambling for Reducing OFDM Peak-to-Average Power Ratio Heshani Gamage, Nandana Rajatheva, Matti Latva-aho University of Oulu c
- 2. 2 Outline OFDM Introduction PAPR Problem Proposed Method Simulation Results c
- 3. 3 OFDM Introduction A digital multi-carrier modulation method where large number of closely spaced orthogonal sub-carrier signals are used to carry data on several parallel data streams or channels. x(t) = 1 N N−1 k=0 Xkej2πfkt ; 0 ≤ t < NT (1) Resilient to multipath fading, inter-symbol interference (ISI), co-channel interference and impulsive parasitic noise, due to multiple narrow band sub channels with a lower data rate on each sub channel. Lower implementation complexity compared with the single carrier solution with usage of Fast Fourier transform (FFT)/Inverse FFT (IFFT) blocks. Has a high spectral efficiency due to usage of closely spaced overlapping subcarriers. c
- 4. 4 OFDM System Model Figure: OFDM System Model c
- 5. 5 Drawbacks of OF OFDM High Peak-to-Average Power Ratio(PAPR). Sensitive to carrier offset and drift. c
- 6. 6 Peak-to-Average Power Ratio of OFDM For better approximation of the PAPR of continuous-time OFDM signals, OFDM signal samples are obtained by L times oversampling. L-times oversampled IFFT output can be expressed as 1 , x [n] = 1 √ N N−1 k=0 Xkej 2πnk LN ; 0 ≤ n < LN − 1 (2) PAPR of OFDM signal, PAPR{x [n]} = max0≤n≤NL |x [n] |2 E [|x [n] |2] (3) 1T. Jiang and Y. Wu, ”An Overview: Peak-to-Average Power Ratio Reduction Techniques for OFDM Signals” in IEEE Transactions on Broadcasting , vol. 54,no. 2,pp. 257–268 , 2008. c
- 7. 7 PAPR Problem Figure: Sum power and average power of a composite signal of 4 subcarriers N base stations (BSs) and K users. c
- 8. 8 PAPR Problem ctd. Figure: Signal Power and Average Power of an OFDM Signal with 1024 subcarriers Figure: CCDF of the PAPR of OFDM signal with 1024 subcarriers c
- 9. 9 Effect of subcarriers on PAPR Figure: CCDF of OFDM PAPR for different number of subcarriers c
- 10. 10 Drawbacks of high PAPR Distortion of the signal if the transmitter has nonlinear components such as power amplifiers (PAs). Nonlinear devices will cause spectral spreading, inter modulation and constellation distortion. To avoid this, usage of expensive high power amplifiers in a very large linear range, approximately equal to the dynamic range of the OFDM signal is required. High PAPR signals prevent PA from operating in near saturation region reducing the PA efficiency. c
- 11. 11 PAPR Reduction Schemes Clipping and Filtering. Selective Mapping (SLM). Coding / Complement block coding. Partial Transmit Sequence (PTS). Tone reservation and tone injection. Nonlinear companding (µ-law / exponential companding ). Almost all the methods have one or more above drawbacks of High computational complexity. Degradation in BER Performance. High average power and requirement of additional transmit power. Bandwidth expansion or spectral spillage. c
- 12. 12 Selective Mapping U different OFDM signals are generated as candidates for a specific signal and then one with the lowest PAPR is selected for the actual transmission. At the receiver, it is necessary to know which one of U candidates is transmitted. Hence transmission of side information is needed in conventional methods resulting a data rate loss. There are several techniques to generate different OFDM signals including, phase rotation and turbo coding. Usually the complexity is very high due to its requirement of calculating U × N IFFTs whenever SLM is applied for an OFDM system with N subcarriers. c
- 13. 13 For a small number of N, the probability that the PAPR of the OFDM signal exceeds a certain threshold λ is given by2 , Pr{PAPR > λ} = 1 − (1 − e−λ )N (4) In SLM it is assumed that, U statistically independent alternative sequences, which represent the same information are generated by some suitable means. The sequence with the lowest PAPR is selected for transmission. The probability that the lowest PAPR λl exceeds a certain threshold λ is given by3 , Pr{λl > λ} = (Pr{PAPR > λ})U (5) 2S. Shepherd, J. Orriss, and S. Barton, Asymptotic limits in peak envelope power reduction by redundant coding in orthogonal frequency division multiplex modulation, in IEEE Transactions in Communications, vol. 46, no. 1, pp. 5-10, Jan. 1998. 3R. W. Bauml, R. F. H. Fisher,J. B. Huber, Reducing the Peak-to-Average Power Ratio of Multicarrier Modulation by Selected Mapping in IEE Electronics Letters, vol. 32, no. 22, pp. 2056-2057, Oct.1996 c
- 14. 14 Proposed Method Since all the signals do not exceed the threshold (About 85% of sequences will exceed a 7dB threshold and about 42% sequences will exceed an 8dB), we apply the PAPR reduction scheme only for those signals which exceed the PAPR threshold. We keep an array of U scramblers to change a high PAPR sequence into a lower PAPR sequence. Once the PAPR of the scrambled sequence goes below the threshold, the scrambling will be terminated and the scrambled sequence will be transmitted, reducing the computational Complexity. c
- 17. 17 Scrambler and Descrambler Figure: Scrambler for an N length sequence Figure: Descrambler for an N length sequence These scramblers can be defined by the scrambler polynomial P where, P = [ 1 P1 P2 ... PS] ; PS ∈ {1, 0} for s = 1..S c
- 18. 18 Simulation Parameters In order to verify the performance of the high PAPR sequence scrambling in reduction of PAPR, we considered a base band OFDM system with the number of subcarriers N = 128 throughout the computer simulations. The oversampling factor is L is set to 4. Randomly generated input data is modulated by 16-quadrature amplitude modulation (16QAM). We used an array of U = 15 scramblers for PAPR reduction throughout the simulations so that only one subcarrier is needed for side information. c
- 19. 19 Simulation Results with 8dB as the threshold Figure: PAPR comparison of OFDM and proposed technique 128 subcarriers with 8dB threshold and 15 scramblers Figure: Percentage of sequences which has used each scrambler for Th = 8dB. Zero means no scrambler is used c
- 20. 20 Simulation Results with 8dB as the threshold Although 15 scramblers are used in this case, it can be seen from the histogram that More than 58% of the sequences do not need any scrambler. About another 25% of signals go below threshold after the 1st scrambler. About 10% more of signals get below threshold after 2 scramblers. Another 4.3% of signals go below threshold after 3 scramblers. Only 0.4% sequences need more than 5 scramblers. Less than 0.007% sequences have to use more than 10 scramblers to achieve PAPR below threshold. Hence this technique reduces the computational complexity of the original SLM technique as it does not need to compute all U candidate sequences and choose the optimum. c
- 21. 21 Simulation Results with 7dB as the threshold Figure: PAPR comparison of OFDM and proposed technique 128 subcarriers with 7dB threshold and 15 scramblers Figure: Percentage of sequences which has used each scrambler for Th = 7dB. Zero means no scrambler is used c
- 22. 22 Figure: CCDF of OFDM PAPR for different numbers of subcarriers N Figure: Performance of the system with increasing number of subcarriers N, for threshold Th c
- 23. 23 Comparison with existing PAPR reduction methods4 5 4T. Jiang and Y. Wu, ”An Overview: Peak-to-Average Power Ratio Reduction Techniques for OFDM Signals” in IEEE Transactions on Broadcasting , vol. 54,no. 2,pp. 257–268 , 2008. 5D.J.G. Mestdagh, ”Reduction Peak-to-Average Power Ratio of OFDM Systems: A Tutorial Overview”,2014 c
- 24. 24 Conclusion Search for a low PAPR sequence will be terminated when a sequence is generated with PAPR lower than the preset threshold. Hence computational complexity of this method is significantly decreased from the conventional SLM method. Proposed technique is effective in reducing PAPR more than 4 dB of the original signal for an arbitrary number of subcarriers. We can find a compromise between PAPR reduction and computational complexity by selecting an appropriate threshold value and the overhead of scrambler index side information can be used for trade off in PAPR reduction capability by choosing a suitable value as the size of the scrambler array. c