EXTENDING OFDM SYMBOLS TO REDUCE POWER
CONSUMPTION
Andr´e B. J. Kokkeler and Gerard J. M. Smit
Department of Computer Science, Electrical Engineering and Mathematics, University of Twente,
PO Box 217, 7500 AE Enschede, The Netherlands
Keywords:
Correlation, Differential Phase Shift Keying, Fourier Transforms, Frequency Division Multiplexing, Modula-
tion.
Abstract:
Existing communication standards have limited capabilities to adapt to low SNR environments or to exploit
low data rate requirements in a power efficient way. Existing techniques like e.g. control coding do not
reduce the computational load when reducing data rates. In this paper, we introduce differential Extended
Symbol OFDM (differential ES-OFDM) which is based on the transmission of symbols that are extended
in time. This way it can operate at low SNR. Using differential BPSK modulation, approximately 2.1 dB
SNR improvement per doubling of the symbol length (halving the bitrate) is obtained. The sensitivity to
frequency offsets of differential ES-OFDM is basically independent of symbol extension. Extending symbols
reduces the computational load on the radio modem within the transmitter which is essential to reduce overall
power consumption. The differential ES-OFDM receiver architecture also offers opportunities to reduce power
consumption.
1 INTRODUCTION
A general trend in modern society is an increasing
emphasis on considerate use of resources, a trend
which can also be observed within Wireless Com-
munications. Besides the reduction of direct energy
consumption, one of the aims is to reduce the polu-
tion of the EM spectrum as much as possible to not
disturbe other users and to minimize human exposure
to EM radiation. Considerate use of resources is ap-
plicable to both infrastructure of wireless communi-
cations systems (e.g. basestations) as well as hand-
held devices. For handhelds, an additional incentive
to reduce power consumption is increased operational
time. For both mobile phones as well as laptops,
backlight and the wireless interface use most of the
energy, see (Carroll and Heiser, 2010) and (Mahesri
and Vardhan, 2005) respectively. Backlight power
consumption is generally counteracted with agressive
backlight dimming while techniques to reduce power
consumption within the wireless interface are less ob-
vious. According to (Carroll and Heiser, 2010) and
(Perrucci et al., 2011), to save power within handheld
devices and to reduce EM radiation, one should con-
centrate on the wireless radio interface of transmit-
ters. This interface can be separated into the Power
Amplifier (PA) and the radio modem which runs the
transceiver algorithms (physical layer) and Medium
Access Control protocols (MAC layer). To reduce
power consumption in a wireless radio transmitter in-
terface, the power consumption in the PA and the
power consumed by the radio modem should be re-
duced evenly (Rantala et al., 2009).
In OFDM systems, given a specific modulation
scheme (e.g. 16-QAM), minimum Signal-to-Noise-
Ratio (SNR) constraints have to be satisfied at the re-
ceiver to achieve acceptable Bit Error Rates (BERs).
In case data rate requirements are reduced, lower-
ing the modulation scheme leads to lower power con-
sumption and lower radiated power levels. Once ar-
rived at the lowest modulation level (BPSK), other
techniques have to be used to reduce power levels.
All options mentioned in section 2 result in more
complexity at the transmitter and/or receiver thus
leading to lower data rates against higher power con-
sumption. This conflicts with our conclusion that,
for effective power reduction, both the power trans-
mitted (consumed in the PA) and the power con-
sumed by the radio modems should be reduced. In
this paper we propose an OFDM technique which
enables the reduction of radiated power levels lead-
ing to lower data rates and lower power consump-
257
B. J. Kokkeler A. and J. M. Smit G..
EXTENDING OFDM SYMBOLS TO REDUCE POWER CONSUMPTION.
DOI: 10.5220/0003950002570262
In Proceedings of the 1st International Conference on Smart Grids and Green IT Systems (SMARTGREENS-2012), pages 257-262
ISBN: 978-989-8565-09-9
Copyright
c
2012 SCITEPRESS (Science and Technology Publications, Lda.)
tion. It is based on differential encoding of data and
the extension of symbols in time and we will refer
to it as differential Extended Symbol OFDM (differ-
ential ES-OFDM). After describing this technique in
section 3, a BER analysis is presented in section 4.
Using BPSK modulation, theoretical BER curves for
AWGN channels are presented. Estimated and simu-
lation results for both AWGN channels and frequency
selective Rayleigh fading channels are presented as
well. In section 5, the effects of frequency offsets are
studied.
2 RELATED WORK
In (Maeda et al., 2002) and (Gaffneyet al., 2005), rep-
etition of symbols in time, allowing less power to be
transmitted, is analyzed. By means of Maximum Ra-
tio Combining, multiple replicas of symbols are used
to minimize the BER. In (Medina and Kobayashi,
2000), repetition of data in the frequency domain is
elaborated. Another option to facilitate lower trans-
mit power is to add error-control coding (Haykin,
2001). Besides that, the efficiency of PA’s can be in-
creased by reducing the Peak-to-Average-Power Ra-
tio (PAPR) of the signal to be transmitted as is done
in e.g. (Harada et al., 2007).
3 DIFFERENTIAL ES-OFDM
A coherent OFDM receiver has to be synchronized
to the transmitter in time, frequency and phase. Es-
pecially phase synchronization is costly to obtain.
Differential modulation disregards the phase infor-
mation at the expense of SNR performance. Both
frequency- and time differential demodulation detec-
tion (FDDD and TDDD respectively) can be used in
an OFDM system (Lott, 1999). FDDD and TDDD
are compared in (Tan and Beaulieu, 2007a) and it
is concluded that FDDD is prefered if the normal-
ized doppler spread dominates the normalized delay
spread. When symbols are extended in time which we
will introduce later on, the normalized doppler spread
increases and the normalized delay spread decreases
(Tan and Beaulieu, 2007a). This makes FDDD more
suited when using time extended symbols.
In Fig. 1, we present a base-band equivalent
model of a differential ES-OFDM system.
At the transmitter, a source produces data vector
S
d
which consists of N −1 complex values (indicated
as S
d
f
, f = 1, 2, ..., N −1) where each value is a con-
stellation point from a chosen modulation scheme.
Enc
DiffS
d
s
ES,L
r
ES,L
r
ES
s
ES
1
I
Σ
Diff Dec
Diff Dec
Diff Dec
IDFT
Channel
I −1
1
0
s
n
S
R
d
R
R
Σ
DFT
DFT
DFT
Figure 1: Base-band equivalent model of differential ES-
OFDM.
We require that |S
d
f
| is constant for all f. S
d
is used to
modulate carriers S by means of differential encoding
S
f
= S
f−1
·S
d
f
, f = 1, 2, ..., N −1 (1)
S
0
= 1 (2)
S is transformed into the time domain through the
IDFT giving s.
s
t
=
1
√
N
N−1
∑
f=0
S
f
e
j
2πft
N
, t = 0, 1, ..., N −1 (3)
I copies of s are concatenated giving the extended
symbol s
ES
.
s
ES
t
= s
MOD(t,N)
, t = 0, 1, ..., IN −1 (4)
where MOD(, N) indicates the modulo N operator.
The last L samples of s (L ≤ N) act as a cyclic prefix
completing s
ES,L
. The values of this extended sym-
bol are shifted out serially and transmitted through the
channel. We assume an additive white Gaussian noise
(AWGN) channel adding n to s
ES,L
resulting in r
ES,L
.
r
ES,L
t
= s
ES,L
t
+ n
t
, t = 0, 1, ..., IN −1 (5)
In the receiver, the first step is to remove the cyclic
prefix. The resulting extended symbol is r
ES
. At the
receiver, we identify I blocks, where each block con-
tains N samples
r
t,i
= r
ES
t+iN)
,
t = 0, 1, ..., N −1 and i = 0, 1, ..., I −1
(6)
Each individual block is converted into the frequency
domain. Since the DFT is a linear operation, the sig-
nal and noise parts can be separated.
R
f,i
= DFT(r
t,i
) = S
f
+ N
f,i
,
f = 0, 1, ..., N −1 and i = 0, 1, ..., I −1
(7)
Each individual block is differentially decoded.
This operation is defined as
R
d
f,i
= R
f,i
·R
∗
f−1,i
, f = 1, 2, ..., N −1 (8)
SMARTGREENS2012-1stInternationalConferenceonSmartGridsandGreenITSystems
258
where
∗
indicates the complex conjugate. From the I
blocks of data, corresponding values are averaged:
R
Σ
f
=
1
I
I−1
∑
i=0
R
d
f,i
(9)
Neglecting the noise contributions, assuming channel
gain equals 1 and using (1) to (9), we see that the
output of the receiver equals
R
Σ
f
= |S
f−1
|
2
S
d
f
= S
d
f
(10)
which is the transmitter input.
To asses the computational complexity of ES-
OFDM, we note that, at the transmitter, the rate at
which IDFTs are executed is reduced with a factor
I. The same holds for the differential encoding. We
conclude that the average power consumption at the
transmitter is lowered. At the receiver however, the
number of DFTs and differential decoding operations
is independent of I. Compared to ’normal’ OFDM
(I=1), the rate of operations at the ES-OFDM receiver
is slightly increased because of the summation of I
decoded symbols leading to a slightly higher power
consumption at the receiver.
4 BIT ERROR RATES FOR
DIFFERENTIAL ES-OFDM
SNR performances of differentially modulated car-
riers in AWGN and fading environments have been
studied in e.g. (Miller and Lee, 1998). SNR perfor-
mance of differential OFDM systems has been stud-
ied in (Tan and Beaulieu, 2007a). However, in these
analyses, the symbol length is fixed and the results
are not applicable in case of extended symbols. Our
approach is based on the observation that, although it
is common to describe a differential OFDM receiver
as an FFT followed by a crosscorrelation, the order
of these functions can be exchanged. Restricting our-
selves to BPSK modulation, this allows us to use the
results presented in (Simon and Divsalar, 1992). In
that paper, a continuous time domain analysis of a
DPSK demodulator in case of an AWGN channel is
presented where a bandpass filtered signal is corre-
lated with a delayed version of the same signal. In
Appendix A, we rewrite (9) in such way that, for each
carrier f, R
Σ
f
is the result of the (cross-)correlation of
two modulated carriers. Because of the orthogonality
of the carriers, a differential ES-OFDM receiver can
be considered as N −1 parallel DPSK demodulators.
In the expression presented in (Simon and Di-
vsalar, 1992) relating SNR to BER, two parameters
are important. First, the energy per bit over noise
SNR (dB)
BER
I = 16
I = 4
I = 1
Theory
Simulations
Estimates
-10
-8 -6 -4
-2
0
2
4 6
8
10
−3
10
−2
10
−1
10
0
Figure 2: BERs for differential ES-OFDM for an AWGN
channel.
spectral density ratio (
E
N
0
) and second the product
of the bandwidth of the bandpass filter and the in-
tegration time (FT). For differential ES-OFDM us-
ing BPSK, the energy per bit over noise spectral den-
sity ratio equals SNR·I and the bandwidth-integration
time product equals ∆f ·
NI
N∆ f
= I, where ∆f is the
inter-carrier spacing. The final result of (Simon and
Divsalar, 1992), in case of differential ES-OFDM us-
ing BPSK and an AWGN channel, becomes
BER =
1
2
I
e
−(I·SNR)
I−1
∑
i=0
(I ·SNR)
i
i!
I−1
∑
j=i
1
2
j
C
j+I−1
j−i
(11)
C
n
k
=
n!
k!(n−k)!
(12)
This expression can be used to determine the theo-
retical BER for differential ES-OFDM in case of an
AWGN channel. A simulation model has been imple-
mented as well for a system with 64 carriers (N = 64),
a cyclic prefix length of 8 (L = 8), I = 1, 4 and 16.
The results are presented in Fig. 2 and are labeled
with ’Theory’ and ’Simulations’. We see that theory
and simulation correspond and BER performance in-
creases for increasing I.
To explain the SNR improvement as a function of
I, (11) does not give much insight except for I = 1 in
which case it reduces to the standard relation between
SNR and BER for AWGN channels (Haykin, 2001).
We therefore derived an estimate of the relation be-
tween SNR and BER as a function of I in Appendix
B:
BER ≈ 0.5∗e
−SNR
EQ
(13)
where
SNR
EQ
=
I ·SNR
2
+ SNR
p
(I ·SNR)
2
+ 2I ·SNR+ I
2·SNR+ 1
(14)
EXTENDINGOFDMSYMBOLSTOREDUCEPOWERCONSUMPTION
259
SNR (dB)
Improvement (dB)
I = 16
I = 4
I = 1
-10
-8
-6
-4
-2
0
2
4
6
8
0.2
-2
0
2
4
6
8
10
12
Figure 3: SNR improvement for extension factors I = 1, 4
and 16.
We see that increasing I does not lead to a con-
stant equivalent improvement of SNR
EQ
but leads to
an SNR dependent improvement. The improvement
of the equivalent SNR
EQ
, for I = 1, 4 and 16 is pre-
sented in Fig. 3.
For the trivial case where I = 1, no improvement
is obtained. For high SNR, I = 4 and I = 16, the SNR
improvement is close to the maximum improvement
of 3 dB per doubling of I. For lower SNR, the im-
provement degrades because uncorrelated noise (N
1
and N
2
, see Appendix B) become more and more
dominant which will, for very low SNR lead to an im-
provementof 1.5 dB per doubling of I (or equivalently
3 dB per quadrupling of I). Based on (13), BER esti-
mates for I = 1, 4 and 16 have been added to Fig. 2.
The estimates are a bit too optimistic. This is caused
by the fact that, especially the signal and noise cross
products (S
1
N
∗
2
and S
∗
2
N
1
, see Appendix B), do not
resemble an AWGN signal as assumed. Expression
(14) has also been used to determine a BER estimate
for Rayleigh fading channels based on
BER ≈
1
2∗(1+ SNR
EQ
)
(15)
BER estimates, based on (15) are shown in Fig. 4
for I = 1, 4 and 16. Simulations have been done for
these cases with a 7-tap frequency selective Rayleigh
fading channel. These results are also shown in Fig.
4.
Both the simulations and the estimated BER val-
ues show that the BER performance improves with
increasing I. We also see that the estimate is becom-
ing more and more optimistic for increasing I, similar
to the AWGN case.
SNR(dB)
BER
I = 1
I = 4
I = 16
Estimates
Simulations
-10 -8 -6
-4
-2 0 2 4
6
8
10
−2
10
−1
10
0
Figure 4: BERs for differential ES-OFDM for an AWGN
(top) and a 7-tap frequency selective Rayleigh fading chan-
nel (bottom).
5 FREQUENCY OFFSETS
One of the known disadvantages of OFDM, compared
to single carrier systems, is its high sensitivity to fre-
quency offsets. The effects of frequency offsets on
frequency-differential modulation have been studied
in (Miller and Lee, 1998) and (Tan and Beaulieu,
2007b). In these publications, approximations of the
relation between the BER and frequency offsets are
given for fixed symbol lengths. In our contribution
we concentrate on an approximation of the relative
effects of symbol extension.
The frequency offset is modeled by multiplying
the extended symbol before transmission s
ES
with a
factor e
j2πδ
f
t
N
, where δ
f
models the frequency offset.
We define the signal r
ES
t,δ
f
at the receiver as
r
ES
t,δ
f
= s
ES
t
·e
j
2πδ
f
t
N
+ n
t
, t = 0, 1, ..., IN −1 (16)
The starting point of the analysis is the correlator out-
put z as defined in (22) of Appendix A. The signal
related parts of z are rewritten using (16)
z
τ,δ
f
=
1
IN
IN−1
∑
t=0
(e
j
2πδ
f
t
N
s
ES
t
·e
j
2πt
N
)
∗
·
e
j
2πδ
f
MOD(t+τ, IN)
N
s
ES
MOD(t+τ,IN)
(17)
Ignoring the edge effect where t + τ ≥ IN,
e
j
2πδ
f
MOD(t+τ, IN)
N
is approximated by e
j
2πδ
f
(t+τ)
N
. Ex-
pression 17 then becomes
z
τ,δ
f
≈
1
IN
e
j
2πδ
f
τ
N
IN−1
∑
t=0
(s
ES
t
·e
j
2πt
N
)
∗
s
ES
MOD(t+τ,IN)
(18)
SMARTGREENS2012-1stInternationalConferenceonSmartGridsandGreenITSystems
260
The distorting factor e
j
2πδ
f
τ
N
does not depend on the
symbol extension factor I and differential ES-OFDM
is therefore, by approximation, insensitive to ex-
tended symbol lengths with respect to frequency off-
sets.
6 CONCLUSIONS
By extending symbols, differential ES-OFDM can
achieve acceptable BERs at low SNR. For AWGN
and frequency selective Rayleigh fading channels, the
SNR requirement at the receiver to achieve acceptable
BERs is lowered when extending symbols (and inher-
ently, lowering the data rate). In case of fixed channel
conditions, doubling the symbol length reduces the
required radiated power level at the transmitter with
approximately 2.1 dB. This way power consumption
within the PA is reduced. When extending symbols,
the computational load per unit time reduces almost
proportionally for the transmitter. We thus satisfy the
requirement that the power consumed in both the PA
and the radio modem of the transmitter should be re-
duced.
The computational load at the receiver slightly in-
creases when extendingsymbols if we consider the re-
ceiver model presented in Fig. 1. However,as already
indicated in our analysis in Section 4, the receiver ar-
chitecture can also be changed into a crosscorrelation
followed by an FFT. In (Kokkeler and Smit, 2011),
it is shown that such a receiver architecture can be
simplified by reducing the resolution of the Analog-
to-Digital Converters giving ample opportunities to
lower the power consumption of the receiver. This
is still a subject of further research.
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APPENDIX A
The expressions given in section 3 describe a differ-
ential ES-OFDM receiver using a so-called FX corre-
lator. In this appendix, we will rearrange the expres-
sions in such way that the receiver describes an XF
correlator. Using the shift theorem and (8), (9) can be
EXTENDINGOFDMSYMBOLSTOREDUCEPOWERCONSUMPTION
261
rewritten as
R
Σ
f
=
1
I
I−1
∑
i=0
R
f,i
·R
∗
f−1,i
=
1
I
I−1
∑
i=0
R
∗
f−1,i
·R
f,i
=
1
I
I−1
∑
i=0
1
√
N
N−1
∑
t
1
=0
r
t
1
,i
e
j
2πt
1
N
∗
e
j
2πft
1
N
·
1
√
N
N−1
∑
t
2
=0
r
t
2
,i
e
−j
2πft
2
N
(19)
The summation over t
2
can start at any index within a
symbol. We choose to add t
1
to the index.
R
Σ
f
=
1
IN
I−1
∑
i=0
N−1
∑
t
1
=0
r
t
1
,i
e
j
2πt
1
N
∗
e
j
2πft
1
N
·
N−1
∑
t
2
=0
r
(t
1
+t
2
),i
e
−j
2πf (t
1
+t
2
)
N
(20)
If we define t
1
+ iN = t, t
2
= τ and use (6), (20) be-
comes
R
Σ
f
=
1
IN
IN−1
∑
t=0
r
ES
t
e
j
2πt
N
∗
e
j
2πft
N
·
N−1
∑
τ=0
r
ES
MOD(t+τ,IN)
e
−j
2πf (t+τ)
N
(21)
The exponential parts dependent on t can be removed,
and by exchanging the summation order, (21) be-
comes
R
Σ
f
=
N−1
∑
τ=0
1
IN
IN−1
∑
t=0
r
ES
t
e
j
2πt
N
∗
·r
ES
MOD(t+τ,IN)
·e
−j
2πf τ
N
,
√
N · DFT(z
τ
)
(22)
We see that R
Σ
f
is proportional to the DFT of a cross-
correlation result z
τ
. To produce z
τ
, the received
extended symbol r
ES
is correlated with a frequency
shifted version of the same symbol. The frequency
shift corresponds to one carrier spacing.
APPENDIX B
The starting point is the general blockdiagram of a
DPSK demodulator presented in Fig. 5. In this fig-
ure, S
1
and S
2
represent the differentially encoded sig-
nals. N
1
and N
2
are produced by uncorrelated noise
sources. We assume that the variances of the signals
and noise sources equal σ
2
S
and σ
2
N
respectively. The
SNR at each input of the multiplier thus equals
σ
2
S
σ
2
N
.
The two sums S
1
+ N
1
and S
2
+ N
2
are multiplied and
averaged over IN samples. This average is then fed
detector
S
1
+ N
1
BERρ
1
IN
∑
IN−1
i=0
S
2
+ N
2
*
Figure 5: General blockdiagram of a DPSK receiver.
into the detector. Expression 11 describes the relation
between the SNR of the input signal and the BER at
the output of the detector as a function of I. When
keeping the SNR at both inputs of the multiplier con-
stant, increasing I will lead to a higher signal-to-noise
ratio ρ at the input of the detector and a lower BER
at the output of the detector. To estimate the effect of
increasing I, we assume that the SNR improvement at
the input of the detector is not caused by increasing I
(we assume I = 1) but by an increased SNR at both
input of the multiplier. The standard relation between
SNR and BER as given in (Haykin, 2001) is used to
estimate the effect of I.
The signal at the output of the multiplier (see
Fig. 5) consists of 4 parts: the signal related part
(S
1
S
∗
2
) and three noise related parts (S
1
N
∗
2
, S
∗
2
N
1
, and
N
1
N
∗
2
). After averaging, we assume that the noise re-
lated parts show Gaussian behavior. In case I = 1, the
signal-to-noise ratio ρ at the input of the detector is
approximated by
ρ
I=1
≈
σ
4
S
2·σ
2
S
σ
2
N
+ σ
4
N
=
SNR
2
2·SNR+ 1
(23)
Extending the symbol increases ρ with a factor I. To
determine the signal-to-noise ratio of a non-extended
input signal (SNR
EQ
) that results in the same ρ as
when extending a symbol with I, we formulate the
following equation
(SNR
EQ
)
2
2·SNR
EQ
+ 1
=
I ·SNR
2
2·SNR+ 1
= ρ
I
(24)
Rewriting this equation leads to the following solu-
tion:
SNR
EQ
=
I ·SNR
2
+ SNR
p
(I ·SNR)
2
+ 2I ·SNR+ I
2·SNR+ 1
(25)
The estimate of the equivalent SNR can be used
within the well knownBER expressions (see (Haykin,
2001))for both AWGN and Rayleigh fading channels.
For AWGN channels, this leads to the following ex-
pression
BER ≈ 0.5∗e
−SNR
EQ
(26)
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