New scheme for PAPR reduction in FBMC-OQAM systems based on combining TR and deep clipping techniques

International Journal of Electrical and Computer Engineering (IJECE)
Vol. 11, No. 3, June 2021, pp. 2143~2152
ISSN: 2088-8708, DOI: 10.11591/ijece.v11i3.pp2143-2152  2143
Journal homepage: http://ijece.iaescore.com
New scheme for PAPR reduction in FBMC-OQAM systems
based on combining TR and deep clipping techniques
Salima Senhadji1
, Yassine Mohammed Bendimerad2
, Fathi Tarik Bendimerad3
1,3
LTT Laboratory, Department of Telecommunication, Abou Bakr Belkaid University, Algeria
2
Department of Electrical and Electronic Engineering, University of Bechar, Algeria
Article Info ABSTRACT
Article history:
Received Apr 5, 2020
Revised Jul 21, 2020
Accepted Sep 22, 2020
Filter bank multi-carrier with offset quadrature amplitude modulation
(FBMC-OQAM) system is a very efficient multicarrier modulation technique
for 5G, but it suffers as all multicarrier designs from large peak-to-average
power ratio (PAPR). Tone reservation (TR) is a method designed to solve
this problem by reserving several subcarriers called tones in the frequency
domain to generate a cancellation signal in the time domain to eliminate high
peaks. In this paper, we suggest a serial combination of tone reservation (TR)
method with an enhanced version of clipping called deep clipping (DC)
method (TR&DC) to enhance the peaks (PAPR) mitigation in FBMC-
OQAM signal model without signiﬁcantly impacting the quality of
transmission. Numerical results and analysis show that the new TR&DC
approach allows better overall performance and offers remarkable gain in
term of PAPR mitigation than the TR method, with similar BER performance
to TR over additive white Gaussian noise channel and Rapp HPA model.
Keywords:
Deep clipping
FBMC-OQAM systems
PAPR reduction
Tone reservation
TR&DC
This is an open access article under the CC BY-SA license.
Corresponding Author:
Salima Senhadji
LTT Laboratory, Department of Telecommunication
Abou Bakr Belkaid University
Tlemcen, 1300, Algeria
Email: salima.senhadji@student.univ-tlemcen.dz
1. INTRODUCTION
The 5G air interface, expected for 2020, have to meet new requirements. Similarly, to 4G it should
support users with great data rates and an important number of machine subscribers with low latency and
energy efficiency [1]. Orthogonal frequency division multiplexing (OFDM) as a multicarrier technique used
in 4G thanks to its closely spaced orthogonal tones, easy implementation and low complexity. Unfortunately,
OFDM has some drawbacks that do not allow it to be adopted for 5G systems. Filter bank multicarrier with
offset quadrature amplitude modulation (FBMC-OQAM) is the most interesting design proposed for the next
5G mobile communication physical layer [2], because it is very good localized in frequency domain, due to
the specific prototype filter PHYDYAS which is well localized in both frequency and time. Thus, we can say
that FBMC-OQAM assumes an optimal use of the frequential spectrum [3]. Nevertheless, the FBMC-OQAM
suffers from large envelope fluctuations known as peak-to-average power ratio (PAPR) [4]. Furthermore, if a
time domain signal with an important dynamic passes through a high power amplifier with insufficient linear
zone, it could produce several in/out of band distortions [5], which lead to adjacent channel interference
(ACI) (spectral regrowth) and to BER degradation.
To solve this high envelope ﬂuctuations problem, various methods for PAPR mitigation have been
suggested for OFDM system. The most used techniques are: clipping [6], coding schemes [7], nonlinear
companding transforms [8], selected mapping (SLM) [9], tone reservation (TR) [10], and partial transmit

 ISSN: 2088-8708
Int J Elec & Comp Eng, Vol. 11, No. 3, June 2021 : 2143 - 2152
2144
sequences (PTS) [11]. These methods reduce the PAPR of OFDM signal with generally negligible
degradation of BER. Some techniques present high computational complexity as PTS and SLM.
Due to overlapping nature of FBMC-OQAM, a lot of new approaches to reduce PAPR have been
recommended to get a better reduction than the conventional schemes. In [12], overlapped SLM (OSLM)
technique was proposed to enhance the conventional SLM. Recently, in [13], the authors suggested
dispersive SLM (DSLM) for the PAPR reduction in FBMC-OQAM system and dispersive TR. In [14], the
authors suggested a multi-block joint optimization (MBJO) to ﬁt the PTS method with the overlapping nature
of the FBMC-OQAM scheme. In [15], the TR scheme for reducing the PAPR in FBMC-OQAM signal was
enhanced by using the sliding window (SW) algorithm. Also, in [16-18], the authors have proposed an
extension of the classical TR and ACE methods to the FBMC-OQAM and a novel method called Multi-
blocks selective mapping (MB-SLM). In [19], a joint solution with SLM and TR was addressed to achieve
better PAPR reduction. A solution was proposed in [20], named TR-PTS hybrid approach with a multi data
block-PTS by taking advantage of the FBMC-OQAM symbol overlaps. The crucial drawback of all these
proposed methods is their high numerical complexity.
In this paper, we propose a new hybrid solution called TR&DC for PAPR mitigation in FBMC-
OQAM signals which combines tone reservation (TR) and deep clipping (DC) techniques. For the new
TR&DC scheme, the first step is to treat the original FBMC-OQAM signals via the TR approach. Since some
peak power of the original signals mostly occurs at some positions, we only need to perform a deep clipping
function for achieving the best reduction. The simulation results are used to show the effectiveness of the
proposed TR&DC scheme in reducing the power envelope ﬂuctuations for FBMC-OQAM signals.
The organization of this paper is as follows: In section 2, we introduce the FBMC-OQAM signal
and PAPR in detail, also tone reservation and deep clipping techniques for PAPR reduction, and we present
the proposed TR&DC scheme. In section 3, we show our simulation results of the new TR&DC scheme and
discussions. Finally, a general conclusion is stated in section 4.
2. RESEARCH METHODS
2.1. FBMC-OQAM signal model and PAPR
The FBMC-OQAM transmitter model [21] is presented in Figure 1, where represents the
subcarriers amount and is the number of input symbols. The input symbol is written as follows:
(1)
are imaginary and real parts of the complex symbol on the subcarrier respectively.
For Offset QAM, the both real and imaginary parts of the QAM symbols are spaced in time domain by ,
where is the symbol duration. After that, the complex symbols are passed on a filter bank of transmission.
The FBMC-OQAM transmission symbol can be obtained by combining all subcarriers signals, which is
written as follows:
( ) ∑ , ( ) ( )- ( )
(2)
where ( )is the prototype filter impulse response.
We consider the PHYDYAS filter (physical layer for dynamic spectrum access and cognitive radio
filter) as the prototype filter. PHYDYAS filter [22] design is based on the frequency sampling method where
the impulse response is:
( ) {√
0 ∑ ( ) . /1 , - (3)
where:
, ∑ - (4)
√
√
(5)

Int J Elec & Comp Eng ISSN: 2088-8708 
New scheme for PAPR reduction in FBMC-OQAM systems based on combining TR … (Salima Senhadji)
2145
Figure 1. The FBMC-OQAM transmitter
From the overlapping process of FBMC-OQAM data symbols depicted in Figure 2, it is clear that
every data of block signal consists of two parts real ( ) and imaginary ( )which are spaced by .
Additionally, the length of one data block is( ) . The length of total consecutive data blocks
is ( ) . The symbol ( ) overlaps with the following data block signal. The total
FBMC-OQAM symbols are given as:
( ) ∑ ( ) . / (6)
Figure 2. The FBMC-OQAM signal structure

 ISSN: 2088-8708
2146
According to the previous paragraph, we need to redefine PAPR for this system. We consider the
FBMC-OQAM burst transmission; there are both initial transition phase and final one in an FBMC-OQAM
burst. Therefore, the signal in few area of the transition is very small. The power peak of the FBMC-OQAM
signal appears in the middle zone, where we can calculate the PAPR of FBMC-OQAM signals. In this
respect, we consider that the both transition phases (initial and final) are equal to ( ) symbol
periods. The middle part is from ( ) to ( ) with points that are then
divided into intervals equally with period . Thus, the PAPR of each interval is defined by (7). We use
CCDF (complementary cumulative distribution function) to analyse the PAPR performance of FBMC-
OQAM signals, which is determined as the probability that PAPR surpass a specific threshold .
( )
( ) (| ( )| )
(| ( )| )
(7)
where * + denotes the expected value and .
( ) ( ) – . – –
/ (8)
2.2. Tone reservation technique for FBMC-OQAM PAPR reduction
Tone reservation (TR) was ﬁrst introduced in [23]. The basic idea of TR scheme is to isolate energy
used to cancel high peaks to a predeﬁned set of subcarriers, termed peak reserved tones (PRTs). These
reserved subcarriers do not transport any useful information and are orthogonal to the data tones (DTs). In
other words, the TR scheme consists to add a time domain signal ( ) to the original signal ( ) to reduce its
peaks as shown in Figure 3. But the resulting PAPR of ( ( ) ( )) must be lower than the original PAPR
of ( ) In the TR based on an iterative clipping filtering algorithm, the total tones are divided into peak
reduction tones (PRTs) and data tones. The positions of the PRTs are known by both transmitter and
receiver. The detailed procedure of TR scheme for FBMC-OQAM signals is described as follows:
First, we divide the data block in frequency domain into a data vector and peaks (PAPR)
reduction vector given as:
{ (9)
{ (10)
where * + is the set of tones reserved for peaks canceling, is the set of data tones, and
is the complement set of in * +
Figure 3. Tone reservation principle

2147
The data subcarriers in time domain ( )are produced by point IFFT operation of . Then, ( )
is clipped to a threshold as:
( )
̅̅̅̅̅ {
( ) | ( )|
| ( )|
(11)
where ( ) | ( )| , is the phase of ( ). We calculate the original clipping noise ( ) as:
( ) ( )
̅̅̅̅̅ – ( ) (12)
2 (13)
where ( ). Finally, we add the time domain peaks reduction signal ( ) to ( ) and the PAPR of the
new TR FBMC-OQAM signal can be expressed as:
( ) ( ) | ( ) ( )|
,| ( )| -
(14)
2.3. Deep clipping technique
Deep clipping [24] is an enhanced version of clipping. It has been suggested to solve the problem of
peaks regrowth. The classical clipping is modified to deeply clip the high amplitudes. A parameter has been
delivered referred to clipping depth factor in order to manage the depth of the clipping. The deep clipping
(DC) function shown in Figure 4 can be expressed as below (where is the clipping depth factor
and is clipping level).
( )
̌
{
( ) | ( )|
( ( ) ) | ( )|
| ( )|
(15)
Figure 4. Deep clipping function
2.4. Proposed combined TR&DC technique for FBMC-OQAM PAPR reduction
In this subsection, we describe our proposed hybrid TR&DC scheme which combines tone
reservation (TR) and deep clipping (DC) methods for PAPR reduction in FBMC-OQAM signals as shown in
Figure 5. These two schemes can be complementary, the TR method reduces some peaks in a FBMC-OQAM
symbol, but a few peaks of the complex symbol cannot be canceled by this way, and will be affected by the
non-linearity of the HPA. For this, we propose to apply the deep clipping function to deeply cancel any high
peaks. This suggested PAPR reduction technique combines the advantages of linearity from the first step
(TR) with the reduced computation complexity of the second step (DC), providing a better PAPR reduction
with good efficiency.

 ISSN: 2088-8708
2148
Figure 5. The new combined TR&DC scheme
The steps of the new proposed TR&DC algorithm can be summarized as:
Proposed algorithm
1. Specify a desired clipping threshold , the numbers of iteration and reserved tones
for TR.
2. Generate the time domain signal ( ) of the data blocks at the output of the FBMC-OQAM
transmitter side using (6).
3. Clip the FBMC-OQAM signal at by using (11).
4. Generate a peak power cancelling signal by :
 Calculate the clipping noise using equation (12) ( ).
 Convert it to the frequency domain ( ).
 Remodulate ( ) to get ( ).
5. Calculate the new TR FBMC-OQAM by adding ( ) to ( ) .
6. Clip the new TR FBMC-OQAM signal by deep clipping function (15) at threshold and the
clipping depth factor .
7. Calculate the PAPR of the new combined TR&DC FBMC-OQAM signal by (7).
3. SIMULATION RESULTS AND DISCUSSIONS
In this section, the simulation results of the new combination TR&DC for the PAPR mitigation in
FBMC-OQAM signals are represented. The considered FBMC-OQAM system is taken with
subcarriers. The prototype filter is PHYDYAS with overlapping factor equal to the length of the filter
is . For the TR scheme, PRTs are . All data are modulated. The iteration times for the TR is
and the clipping level is taken . For deep clipping technique the depth factor is taken
and . PAPR performances are analyzed using CCDF plots.
From Figure 6 (a), we see that the PAPR of unchanged FBMC-OQAM, for a the
PAPR threshold is . When we apply TR technique, it significantly reduces from to
for the same . In the hybrid TR&DC FBMC-OQAM, for a the PAPR is
. The reduction gain of the new combination TR&DC is about . We can remark that, this new
TR&DC method presents an important gain in term of reduction. PAPR reduction gain depends on many
parameters such as clipping level, the number of peak reduction tones, clipping depth factor and the number
of iterations.
The temporal evolution of the new TR&DC scheme, TR and the original FBMC-OQAM signal are
presented in Figure 6 (b). Peaks power of the considered signals appears at some points. Compared with the
original signal, the combination TR&DC can efficiently cancel the peaks power of the signal better than the
TR only. In Figures 7 (a) and (b), we show the PAPR reduction of the suggested TR&DC scheme with
different clipping thresholds and different depth factors with fixed parameters:
. is selected as respectively, and is selected as . It is
illustrated that the variation of the threshold ( ) and the depth factor ( ) may not contribute in reducing
PAPR. Because in both figures, all results are around with a slight difference. Different numbers of
PRTs ( ) of the new scheme are depicted in Figure 7 (c). When the number of PRTs is , with
fixed parameters: . It can be observed that for compared with the
original signal at , the PAPR reduction gain of the new TR&DC is . Evidently,
increasing the number of PRTs could considerably enhance the PAPR mitigation for the TR&DC approach.
Then, we have executed the same algorithm using different iterations when the fixed
parameters are , as shown in Figure 7 (d). From Figure, we note that the PAPR
threshold decreases as the increasing of . When and , the threshold value of the new
TR&DC with is . As simulation results show, the TR&DC method have enhanced the peaks
mitigation (PAPR) and we just have to select the optimal combination of parameters to get the best
performance.
The BER simulations are shown in Figure 8 for the new TR&DC, TR and the original FBMC-
OQAM when the channel between the transmitter and the receiver is taken as an additive white Gaussian
noise (AWGN) channel and at various values of SNR. From Figure, we see that the TR plot coincides with
TR&DC plot and present acceptable BER performance.

2149
(a) (b)
Figure 6. CCDFs and time evolution of TR&DC, TR schemes and original FBMC-OQAM signal
(a) (b)
(c) (d)
Figure 7. CCDFs plots of the new TR&DC scheme using different parameters

 ISSN: 2088-8708
2150
Figure 8. BER of TR&DC, TR schemes and original FBMC-OQAM over AWGN channel
Finally, a nonlinear high power ampliﬁer model is introduced to observe the performance of our
TR&DC method in term of BER performance. The HPA follows the Rapp model with a smoothness factor
that controls the transition between the linear area of the HPA and the saturation one. The Rapp model
[25] presents only AM/AM conversion. This one can be denoted as:
( ( ))
( )
( (
( )
) )
(16)
( ( )) (17)
where the smoothness factor is all time From Figures 9 (a) and (b), we can observe that the proposed
TR&DC and TR technique perform similarly even in the presence of Rapp HPA in both scenarios
respectively. But as we know, the BER results depend on the IBO (the BER
measurements improve when the IBO increases for the original FBMC-OQAM signal).
(a) (b)
Figure 9. BER of TR&DC, TR schemes and original FBMC-OQAM with Rapp HPA over AWGN channel,
(a) IBO=0dB, (b) IBO=7dB

2151
4. CONCLUSION
Theoretically the TR cannot eliminate all high power peaks present in multicarrier signals such as in
FBMC-OQAM. The study presented in this article was used to evaluate the possibility to associate a deep
clipping technique which is better than the classical clipping technique with TR method for the FBMC-
OQAM waveform, resulting in a good compromise between the backward compatibility, the linearity of the
TR method and low complexity, simplicity of the deep clipping. In this paper, large number of simulations
have validated that our suggested TR&DC method can achieve excellent PAPR mitigation. From the
simulation results, the new proposed TR&DC method for reducing PAPR in FBMC-OQAM signals present
an improvement in PAPR performance compared to the TR scheme and original FBMC-OQAM signal. For
the new proposed TR&DC scheme, we can adjust parameters of each technique to get the optimal
performance. In addition, over both AWGN channel and HPA with Rapp model the new TR&DC and TR
techniques perform similarly in term of BER performance.
ACKNOWLEDGEMENTS
This work was supported by the national project with technological development and socio-
economic impact under code N°13-2019-DGRSDT/Univ Tlemcen, entitled: contribution to the spectral and
energetic efficiency of 5G communications systems.
REFERENCES
[1] J. G. Andrews, et al., “What will 5G be?,” IEEEJ. Sel. Areas Commun., vol. 32, no. 6, pp. 1065-1082, 2014, doi:
10.1109/JSAC.2014.2328098.
[2] F. B. Boroujeny, et al., “Cosine modulated and offset QAM ﬁlter bank multicarrier techniques: a continuous-time
prospect,” EURASIP Journal on Advances in Signal Processing, pp. 1-16, 2010,
[3] F. B. Boroujeny., “OFDM versus Filter Bank Multicarrier,” IEEE Signal Processing Magazine, vol. 28, no. 3,
pp. 92–112, doi: 10.1109/MSP.2011.940267.
[4] S. S. K. C. Bulusu, et al., “Reducing the PAPR in FBMC-OQAM systems with low-latency trellis-based SLM
technique,” EURASIP Journal on Advances in Signal Processing, pp. 1-11, 2016.
[5] S. Litsyn, “Peak Power Control in Multicarrier Communications,” New York, NY, USA, Cambridge Univ. Press,
2007.
[6] R. O. Neill, et al., “Envelope variations and spectral splatter in clipped multicarrier signals,” Proc. IEEE Int. Symp.
Personal, Indoor Mobile Radio Commun, 1995, pp. 71-75, doi: 10.1109/PIMRC.1995.476406.
[7] A. E. Jones, et al., “Block coding scheme for reduction of peak to mean envelope power ratio of multicarrier
transmission schemes,” IEEE Electronics Letters, vol. 30, no. 25, pp. 2098-2099, 1994, doi: 10.1049/el:19941423.
[8] X. B. Wang, et al., “Reduction of peak-to-average power ratio of OFDM system using a companding technique,”
IEEE Trans. Broadcasting, vol. 45, no. 3, pp. 303-307, Sep. 1999, doi: 10.1109/11.796272.
[9] S. S. Yoo, et al., “A novel PAPR reduction scheme for OFDM systems: Selective mapping of partial tones
(SMOPT),” IEEE Trans. Consumer Electronics, vol. 52, no. 1, pp. 40-43, Feb 2006, doi:
10.1109/TCE.2006.1605023.
[10] J. Tellado., “Peak to Average Power Ratio Reduction for Multicarrier Modulation,” PhD thesis, University of
Stanford, Stanford, 1999.
[11] S. H. Muller, et al., “OFDM with reduced peak-to-average power ratio by optimum combination of partial transmit
sequences,” IEEE Electronics Letters, vol. 33, no. 5, pp. 368-369, Feb 1997, doi: 10.1049/el:19970266.
[12] A. Skrzypczak, et al., “Overlapped selective mapping for pulse-shaped multi-carrier modulations,” IEEE 64th
vehicular technology conference fall, 2006, pp. 1-5, doi: 10.1109/VTCF.2006.169.
[13] S.S.K.C. Bulusu, et al., ”PAPR reduction for the FBMC-OQAM systems using dispersive SLM technique,” 14th
IEEE international symposium on wireless communication systems, pp. 1–5, 2014.
[14] Qu, et al., “Multi-block joint optimization for the peak-to-average power ratio reduction of FBMC-OQAM signals,”
IEEE Transactions on Signal Processing, vol. 61, no. 7, pp. 1605-1613, 2013, doi: 10.1109/TSP.2013.2239991.
[15] Qu, et al., “Sliding Window tone reservation technique for the peak-to-average power ratio reduction of FBMC-
OQAM signals,” IEEE Wireless Communications Letters, vol. 1, no. 4, pp. 268-271, 2012.
[16] M. Laabidi, Rafik Zayani, and Ridha Bouallegue, “A new tone reservation scheme for PAPR reduction in
FBMC/OQAM systems,” 11th international wireless communications and mobile computing conference, 2015, doi:
10.1109/IWCMC.2015.7289196.
[17] M. Laabidi, et al., “PAPR reduction in FBMC/OQAM systems using active constellation extension and tone
reservation approaches,” IEEE Symposium on Computers and Communication (ISCC), pp. 657-662, 2015, doi:
10.1109/ISCC.2015.7405589.
[18] M. Laabidi, Rafik Zayani, and Ridha Bouallegue, “A novel multi-block selective mapping scheme for PAPR
reduction in FBMC/OQAM systems,” World Congress on Information Technology and Computer Applications,
pp. 1-5, 2015, doi: 10.1109/WCITCA.2015.7367014.
[19] S. Vangala, and S. Anuradha., “Hybrid PAPR reduction scheme with selective mapping and tone reservation for
FBMC/OQAM,” 3rd International Signal Processing, Communication and Networking, 2015, pp. 1-5, doi:
10.1109/ICSCN.2015.7219877.

 ISSN: 2088-8708
2152
[20] H. Wang, et al., “Hybrid PAPR reduction scheme for FBMC/OQAM systems based on multi data block PTS and
TR methods,” IEEE Access, vol. 4, pp. 4761-4768, 2016, doi: 10.1109/ACCESS.2016.2605008.
[21] P. Siohan, Cyrille Siclet, and Nicolas Lacaille, “Analysis and design of OFDM/OQAM systems based on ﬁlter bank
theory,” IEEE Trans. Signal Process, vol. 50, no. 5, pp. 1170-1183, 2020, doi: 10.1109/78.995073.
[22] M. Bellanger, et al., ”FBMC physical layer: a primer,” PHYDYAS, 2010.
[23] J. Tellado, “Peak to average power reduction for multicarrier modulation,” Ph.D. dissertation, Stanford University,
Sep. 1999.
[24] S. Kimura, et al., “Par reduction for ofdm signals based on deep clipping,” 3rd International Symposium on
Communications, Control and Signal Processing, ISCCSP 2008, pp. 911-916, 2008, doi:
10.1109/ISCCSP.2008.4537353.
[25] R. Christoph, “Effects of HPA-nonlinearity on a 4-DPSK/OFDM-signal for a digital sound broadcasting signal,”
ESA, Second European Conference on Satellite Communications (ECSC-2), 1991, pp. 179–184.

New scheme for PAPR reduction in FBMC-OQAM systems based on combining TR and deep clipping techniques

More Related Content

What's hot (20)

Similar to New scheme for PAPR reduction in FBMC-OQAM systems based on combining TR and deep clipping techniques (20)

More from IJECEIAES (20)

Recently uploaded (20)

New scheme for PAPR reduction in FBMC-OQAM systems based on combining TR and deep clipping techniques