IRJET- Power Allocation Methods for NOMA based Visible Light Communication

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 06 Issue: 09 | SEP 2019 www.irjet.net p-ISSN: 2395-0072
© 2019, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 1108
Power Allocation Methods for NOMA based Visible Light
Communication
Bevara Siva Prasad1, E.V. Narayana2
1Department of Electronics and Communication Engineering, University College of Engineering, Kakinada, India
2Assistant Professor, Department of Electronics and Communication Engineering, University College of
Engineering, Kakinada, India
---------------------------------------------------------------------***----------------------------------------------------------------------
Abstract – The design of efficient power allocation
methods for Non-orthogonal multiple access (NOMA)
technique is to improve achievable sum rate of multiple-
input multiple-output (MIMO) based multiuser visible light
communication (VLC) systems. In this paper we investigate
that NOMA with normalized gain difference power
allocation (NGDPA) method improves sum rate up to
47.6%.And compared with gain ratio power allocation
(GRPA) method with six and seven users.
Key Words: Multiple-input multiple-output (MIMO),
visible light communication (VLC), non-orthogonal
multiple access (NOMA)
1. INTRODUCTION:
To increase the number of smart phones, tablet and
data-required applications like video streaming, wireless
data traffic is expected to increase by a factor of 100. In
the year 2010 this requirement was as high as 3 Exabyte’s.
This requirement is expected to increase 500 Exabyte’s by
2020[1]. Therefore future wireless networks require more
network capacity. Several 5G technologies such as mm
wave and VLC [2] and MIMO etc.. for supporting next
generation high speed wireless communication systems
require more capacity. VLC is one of the 5G technologies is
promising for convenient deployment, natural
confidentiality, low energy consumption etc. visible light
communication(VLC) is particularly used in
electromagnetic sensitive areas such as hospitals, aircraft
cabin etc.
As a wireless broadband technology, it is essential that
VLC systems can efficiently support multiple users with
simultaneous network access [3]. Therefore multiple
access techniques are essential in the multiuser VLC
systems. Few multiple access techniques are time division
multiple access (TDMA), FDMA, CDMA etc.. However these
techniques cannot provide sufficient resource reuse.
OFDMA is used to VLC systems to reduce required data
rate due to the spectrum partitioning. NOMA has been
recently proposed for 5G wireless networks due to its
superior spectral efficiency [4]. NOMA system uses power
domain for multiple users are multiplexed at the
transmitter side by superposition coding and successive
interference cancellation (SIC), is for multiuser signal
separation at the receiver side [5]. Multiple-input and
multiple-output (MIMO) has been widely applied in VLC
systems provides additional degree of freedom for future
performance improvement. Few power allocation
strategies are in MIMO-NOMA based VLC systems, such as
fixed power allocation strategy (FPA), post detection [6],
hybrid preceding and signal alignment [7] etc. However
these methods have high computational complexity.
In this paper we apply normalized gain difference
power allocation (NGDPA) method in MIMO-NOMA based
VLC systems. It is shown that MIMO-VLC system can be
greatly improving achievable sum rate by employing
NOMA with the proposed NGDPA method in comparison
to NOMA with gain ratio power allocation (GRPA).
Fig. 1: Illustration of a 4 MIMO-NOMA-based VLC
system with n users.
2. SYSTEM MODEL:
In section 2 we describe the mathematical model of a
MIMO-NOMA based multiuser VLC system. Fig 1: shows
that indoor 4 4 MIMO-NOMA based VLC system with n
users. Each user is equipped with two photodiodes and
each user can use entire modulation.

Fig.2. Block diagram of a 4 4 MIMO-NOMA- based VLC
system using DCO-OFDM modulation with n users.
DCO-OFDM technique can improve the communication
coverage area of indoor MIMO-VLC systems. Fig 2:
illustrates the 4×4 MIMO-NOMA-VLC systems with n
users. We present a general model of indoor MIMO-VLC
systems using DCO-OFDM. The 2×2 MIMO-VLC systems
using DCO-OFDM with one pair of LEDs were evaluated
[3]. In this work we apply a general indoor 4×4 MIMO-VLC
system using DCO-OFDM and it is analytically derived.
Fig 2: shows the 4×4 MIMO-NOMA-VLC system using
DCO-OFDM modulation. Let t) and (t) be the input
signals of LED1 and LED2 respectively. After DCO-OFDM
modulation power domain super position and DC bias
addition. The obtained input signal of the j-th LED (j=1, 2),
) can be represented by
) ∑ √ ) , (1)
Where ) is the signal intended for the n-th
(n=1,2......N) user in the j-th LED, is the electrical
power allocated for the n-th user in the j-th LED, and
is the DC bias for each LED. To ensure a constant over all
electrical power for each LED, the following power
constraint is imposed.
∑ )
Without loss of generality, let .
ξ s+ , (3)
where is the responsivity of the PD, is the output
optical power of the LED, ξ is the modulation index, is
the 4×4 channel matrix of the n-th user, S = [ ]T is the
transmitted electrical signal vector where [·]T is the
transpose operation, and is the additive noise vector.
The detailed calculation of the variances of the additive
noises can be found in [3].
Assuming each LED in MIMO-VLC system follows a
lambertian radiation pattern [2], the LOS optical channel
gain between the j-th LED and i-th detector in the detector
array of the receiver is calculated by
∑
)
µɳ ( ) , (4)
where m= −ln 2∕ ln(cos Ψ) is the Lambertian emission
order; Ψ is the LED’s semi-angle at half-power; L is the
number of LED chips in one LED; A is the detector’s active
area; is the distance between the t-th chip in the j-th
LED and the i-th detector; μ and η are the gains of the
optical filter and lens, respectively; is the emission
angle; and is the incident angle. The important point is
that the optical channel gain becomes zero if the incident
light is outside the field of view (FOV) of the receiver. At
receiver side to recover the transmitted data, MIMO de-
multiplexing, and zero-forcing (ZF) using channel
inversion is used due to its low complexity. Finally to get
the approximate electrical signal vector at the n-th user is
obtained by
̃ =S+ , (5)
Where is the inverse of . Later successive
interference cancellation (SIC) is applied with respect to
each LED at each user. To perform SIC at receiver side
based on decoding order of the users with respect to each
LED should be first determined. In this work we use the
sum of the optical channel gains of each user with respect
to each LED instead of individual optical channel gains to
sort the users, without loss of generality, to sort the users
according to their sum of optical channel gains in the
decreasing order as follows
h1j,1 + h2j,1 > h1j,2 + h2j,2 > · · · > h1j,n + h2i,n ., (6)
The decoding order with respect to the j-th LED is
Dj,1 < Dj,2 < · · · < Dj, n . (7)
Finally we get the data for six and seven users are
obtained via DCO-OFDM demodulation.
3. POWER ALLOCATION METHODS:
In this section two types of power allocation methods
are considered. One is gain ratio power allocation (GRPA)
and the other one is normalized gain difference power

allocation (NGDPA). As illustrated in the following two
subsections respectively.
3.1 GAIN RATIO POWER ALLOCATION (GRPA):
It is low complexity power allocation method is ensure
to evaluate the achievable sum rate of MIMO-NOMA based
VLC systems [8]. In GRPA, power allocation based on
optical channel gain of each user. In this work we use sum
optical channel gain instead of individual channel gain, the
GRPA method can be generalised for MIMO-NOMA based
VLC systems. In the 4 4 MIMO-NOMA-VLC system using
GRPA, according to the decoding order in (7), the
relationship between the electrical powers allocated to
user n and user n + 1 in the j -th LED is given by
) . (8)
3.2 NORMALIZED GAIN DIFFERENCE POWER
ALLOCATION (NGDPA):
NGDPA is proposed for further improvement of the
achievable sum rate of MIMO-NOMA based VLC system. In
NGDPA power allocation depends on optical channel gain
difference. Finally the power allocated to users n and user
n+1 in the j-th LED have the following relationship
)
(9)
We observed from (9), optical channel gain difference is
used instead of sum of optical channel gains as in (8) then
the power is reduced from n+1 to n.
TABLE-1 SIMULATION PARAMETERS
Parameter Value
Vertical distance between the LED and
users
LED semi angle Ψ
Spacing between LEDS
Optical power
Modulation index
Signal bandwidth B
PD active area A
PD responsivity
Optical filter gain µ
Optical lens gain ɳ
Total number of users n
2.15
1m
10W
0.5
10MHZ
1
0.5 ⁄
0.9
2.5
7
4. SIMULATION RESULTS:
In this section we evaluate the performance of a 4 4
MIMO-NOMA based VLC systems with seven users. We set
the normalised offset of user n with respect to user 1 as .
Fig.3. Achievable rate of each LED vs. normalized offset
using NOMA with seven users (n = 7).
Fig3: shows the achievable rate of each LED in 4 4 MIMO-
NOMA based VLC systems with seven users. It shows that
achievable rate of LED1 is 68.8 Mbit/s when 0.1
for GRPA and for NGDPA is 68.6 Mbit/s. when further
increase of , the achievable rate of LED1 using GRPA is
greatly reduced to 49.6Mbit/s at .By using NGDPA
method the achievable rate is slightly reduced with the
further increase of and the achievable rate is
64.1Mbit/s at as can also be seen the achievable
rate of LED2 is almost same at different values for both
GRPA and NGDPA methods. Further increase of that is at
the end of users the achievable rate of LED2 using GRPA is
greatly reduced and it is almost 49.9Mbit/s at In
contrast the achievable rate of LED2 using NGDPA method
is 65Mbit/s at =1. Hence the performance of GRPA
method is poor at far-end users.

Fig.4. Achievable sum rate vs. normalized offset using
OFDMA and NOMA.
Fig.4 shows the comparison of achievable sum rate in
4 MIMO-VLC system employing OFDMA and NOMA . As
we can seen that the achievable sum rate using OFDMA is
continuously reduced with increase of . By using NOMA
with GRPA method the sum rate fluctuates with the
increase of . A fast decrease occurs when 0.6,
indicating that NOMA with GRPA suffers from significant
sum rate loss when becomes relatively large. When
NOMA with NGDPA method is used the performance of
achievable sum rate is improved compared with NOMA
with GRPA method.
Fig.5.spectral efficiency vs bit rate using OFDMA and
NOMA
Fig.5 shows the comparision of spectral efficiency in VLC
systems employing OFDMA and NOMA. As we can seen
that the bit rate employing OFDMA is reduced due to
spectrum partitioning and hence the spectral efficiency of
NOMA will be greater than OFDMA and it shown in the
above fig.5.
Fig. 6. Sum rate gain of NGDPA over GRPA in NOMA vs.
Normalized offset.
Fig.6: shows the sum rate gain of NGDPA over GRPA
versus . Here we can see that the sum rate gain using
NOMA with NGDPA is more efficient comparing NOMA
with GRPA especially at far end of users. For example,
when that is user n is located at the edge of the
system coverage the sum rate gains are 39.3% and 47.6%
for n=6 and n=7 respectively.
5. CONCLUSION:
In this paper NOMA with power allocation methods are
designed to allocate more power to users experiencing
poor channel conditions. It is intended to enhance the data
rate of edge users and alleviate the near-far effect without
degrading the performance of central users. The
simulation results shows that in an indoor 4 4 MIMO-VLC
systems, NOMA with NGDPA method is improved sum rate
than NOMA with GRPA method. In 4 4 MIMO based VLC
systems using NOMA with NGDPA achieves sum rate up to
47.6% with seven users. Therefore, the sum rate of NOMA
with NGDPA over GRPA method is more significant with
more users in the VLC systems.
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IRJET- Power Allocation Methods for NOMA based Visible Light Communication