Parameter Analysis of Semi Deterministic Pathloss against Soft
Handover Performance in Mobile Communication
Maksum Pinem
1
, Muhammad Zulfin
1
, Indah Vusvita Sari
1
, Sri Indah Rezkika
1
1
Electrical Engineering Department, Universitas Sumatera Utara, Padang Bulan, 20155 Medan, Indonesia
Keywords: Radio Propagation Models, Propagation Parameters, Mobile Communication Performances, Simulation
Programming.
Abstract : This research focused on assessment of the parameters semi-deterministic propagation model in effort
enhancement performance soft handover in mobile communication, so obtained characteristic model
propagation parameters affecting relations with enhancement performance soft handover. The method used is
design simulation with computer programming by building a model of virtual mobile communication system
with software. The propagation model and handover model that has been applied in this research are Cost231
Walfisch-Ikegami and soft handover-hysteresis with threshold. The observed parameters were height of
building, street width and distance between buildings. While the performance parameters system wireless
moves are observed, ie : drop call rate, radio link increase rate and active set average rate. From the simulation
result obtained, ie : the increase in height of the building causes decreased radio links, increased drop call
rates and reduction of the average number of active sets. Whereas on the contrary with the width increase
between buildings and street width respectively causing the increase of radio link, decrease of drop call rate
and addition of active set average amount.
1 INTRODUCTION
The Path loss is the electromagnetic wave that
spreads through the space between the transmitter
antenna and the receiver antenna in the
communication system. It can be caused on decline
quality and the strength of radio signals due to the
effects of reflection, refraction, diffraction, scattering
and absorption. The effect are influenced by
environmental conditions, frequency of operation,
distance between transmitter and receiver (O.O. Oni
and F.E. Idachaba, 2017). Although thus, high
mobility of user movement in mobile communication
are caused by the strong fluctuations of the received
signal level as a result of propagation damping,
distance and obstacles the environment is not
irregular (Maksum Pinem, 2014). To maintain the
stability and continuity of mobile communication, a
service switching mechanism called handover is
required .
For the new generation network move needed an
innovative predictive model related with frequency .
On research previous has analyzed six predictions
model of loss different paths and as a whole is the best
choice for a new generation of networks moving
regardless of distance and type of environment
(Aymen Zreikat and Milan Dordevic, 2017).
Caused of high mobility of the MS moving from
one cell to another cause difficulty in backing
prediction signal propagation and effect on signal
strength level of reception. Strong level signals
received by MS is influenced by path loss, shadow
fading and fast fading, as a result of the propagation
and attenuation of irregular circumstances (Singh, N.
P and Singh.B, 2010).
Study on signal radio spreading is very important
in the wireless network within effort keep quality
signal communication and stability continuity
communication move between user (handover),
beside magnitude funds to prepare infrastructure from
communication system wireless. By therefore, this
study are focused on assessment of the parameters of
the semi-deterministic path loss propagation model in
effort to enhancement performance soft handover in
mobile communication, so obtained characteristic
Pinem, M., Zulfin, M., Sari, I. and Rezkika, S.
Parameter Analysis of Semi Deterministic Pathloss against Soft Handover Performance in Mobile Communication.
DOI: 10.5220/0010080502430247
In Proceedings of the International Conference of Science, Technology, Engineering, Environmental and Ramification Researches (ICOSTEERR 2018) - Research in Industry 4.0, pages
243-247
ISBN: 978-989-758-449-7
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
243
model propagation parameters affecting relations
with enhancement performance soft handover, so
expected this research give contribution on guarding
quality signal communication and stability continuity
communication.
2 MODEL DESIGN
In this study, the modeled BS consists of two base
stations. Each BS has the same and separate transmit
power at distance D and mobile station (MS) moves
on a straight path with a regulated speed as shown in
Figure 1 (M. Pinem and R. Fauzi, 2018). As the
mobile station moves, the signal is obtained mobile
station has decreased. This decrease caused of the
distance accreation and obstacle around the base
station to the mobile station. Large signal decrement
in this study is modeled by propagation model Cost
231 Walfisch-Ikegami.
Figure 1: Network model
Received signal strength by mobile station
initiated for soft handover algorithm. Performance of
soft handover consisting of drop call rate, radio link
increase rate, active set average size and handover
rate. Then, soft handover performance will be
observed to the change of radio wave propagation
parameter, ie : building height, street width, and
distance between building.
Walfisch Ikegami COST231 restricted to :
a. Frequency (f
c
) : 800MHz-2000MHz
b. High antenna BS (h
b
) : 4 m - 50 m
c. High MS ( h
m
) : 1 m - 3 m
d. Distance BS and MS (d) : 0.02 km - 5 km.
The COST231 WI model is a suitable model used
for predict unfortunate- loss trajectory in the area city.
This model applied for area where transmitter no
visible on directly by receiver caused the number
object barrier in between transmitter and receiver as
seen on Figure 2 (Maksum Pinem, 2018).
Figure 2: Illustration COST231 models Walfisch -Ikegami
There are four factors that are included in
calculation of path loss for this model , ie (COST
Action 231, 1999) :
a. High building ( h )
b. Wide street ( w )
c. Distance between building ( b )
d. Orientation related street with LOS path (φ) .
This model distinguish between propagation of
LOS and non-LOS. For propagation of LOS, this
model use Equation 1 .
𝐿
42,6 26 log
𝑑
20 log
𝑓
for d 20 meter (1)
For non-LOS propagation , this model use Equation
2.
𝐿
42,6 26 log
𝑑
20 log
𝑓
(2)
where L FSPL is loss room free (free space loss), L
rts is losses resulting by diffraction " rooftop to street
" and L msd is loss estimated effect existence
influence diffraction from the number object barrier
between base station and The nearest building with
mobile station.
The Walfisch-Ikegami COST231 model has be
accepted by body standardization international ITU-
R and could applied for high antenna BS above
rooftop . Mean error allowed is of ± 3 dB and standard
deviation of 4 - 8 dB (Nining Triana, 2015).
3 METHOD
Implementation of this research is done with literature
study, propagation parameter verification Cost231
Walfisch-Ikegami, designing signal transition
generating virtual base station, system model design
virtual communication, Application of soft handoff
algorithm hysteresis threshold for two base station,
determining simulation parameter input data, design
of simulation coding (programming) on overall,
testing the simulation by varying the observed
ICOSTEERR 2018 - International Conference of Science, Technology, Engineering, Environmental and Ramification Researches
244
variables from radio wave propagation model and
analyze the simulation result. The block diagram of
the system shown at Figure 3.
Figure 3: Design of System Model
The parameters used in the simulation are shown
on Table 1. The program simulation in this study uses
MATLAB software and data of research results
obtained based on the data results of running
simulation program that runs repeatedly.
Furthermore, the analysis is done by statistical
methods to see the relationship between input
parameters with system performance parameters
using Microsoft Excel.
Table 1: Simulation Parameters
4. RESULT AND DISCUSSION
Performance analyzed in this study is based on
building height, street width, distance between
building and orientation streets that affect
performance drop cal rate, radio link increase rate,
active set avarage rate and handover rate
.
3.1 Effect of Building Height on Soft
Handover Performance
The relationship between the height increase of the
building on the rate of decreasing the radio link, the
Drop Call rate and the average of the active size is
presented in Table 2.
Table 2: Influence of Building Height on Soft Handover
Performance
It can be observed that with the increasing height of
the building the decrease of Radio Link is higher,
since the height of the building blocks the signal from
BS, as shown at Figure 4. This will impact the
weakening of the signal received by MS. So when the
height of the building is at 29 meters then began to
occur drop call. Drop call more frequent when the
height of the building is set 30 meters. Conversely,
when viewed from the parameter set active, the
increase in the height of the building impact on the
reduction of the number of active sets that serve the
MS.
Figure 4: Link Degradation Rate
3.2 Effect of Street Width on Soft
Handover Performance
The relationship between the increase of the street
width against of the radio link degradation rate, the
Drop Call rate and the average of the active size are
presented in Table 3.
Parameter Analysis of Semi Deterministic Pathloss against Soft Handover Performance in Mobile Communication
245
Table 3: Effect of Street Width on Soft Handover
Performance
It can be observed that with increasing street width
the decrease of Radio Link is lower, meaning the
signal is better because the increase of street width
gives an increase spaciousness and flexibility of
propagation of BS signal emission. This certainly
reduces the signal attenuation that reaches and
received in MS. So when the width of the street is set
at 20 meters then the radio link is in the best
condition, where at this distance there is no drop call
at all, as shown at Figure 5. Therefore, when viewed
from the active set parameter, the increase in the
width of the street has an impact on increasing the
number of active sets that serve the MS.
Figure 5: Drop Call Rate
3.3 Effect of Distance between Building
on Soft Handover Performance
The next observation is the relationship between the
increase of distance between buildings on the rate of
decrease of radio link, Drop Call rate and the average
of active size shown in Table 4.
Table 4: Effect of Distance between Building on Soft
Handover Performance
It can be observed that with increasing width of the
distance between buildings, decrease of Radio Link is
also lower. This means that the increase in signal
strength is better because of the reduced signal barrier
so that the increased freedom of propagation of the
BS signal emission. This of course also affects the
reduction of attenuation signals that reach and receive
in MS. So when the distance between buildings set to
8 to 20 meters then the radio link is in the best
condition of all, where there is no drop call at all.
Likewise, when observed from active set parameters,
the increase of distance between buildings also has an
effect on increasing the
average number of active sets
serving MS toward servant stability, as shown at
Figure 6.
Figure 6: Active Set Size Average
4 CONCLUSIONS
This study has successfully demonstrated the
relationship between semi-deterministic propagation
model parameters and the performance parameters of
soft handover in mobile communications. From the
simulation results obtained that the increase in height
of the building causes decreased radio links,
increased drop call rates and reduction of the average
number of active sets. Whereas on the contrary with
ICOSTEERR 2018 - International Conference of Science, Technology, Engineering, Environmental and Ramification Researches
246
the width increase between buildings and street width
respectively causing the increase of radio link,
decrease of drop call rate and addition of active set
average amount.
ACKNOWLEDGMENT
This research was funded by Research Institute
University of North Sumatera under TALENTA grant
for Research Contract of Fiscal Year 2018.
REFERENCES
Aymen Zreikat and Milan Dordevic. (2017). Performance
Analysis of Path loss Prediction Models in Wireless
Mobile Networks in Different Propagation
Environments. Proceedings of the 3rd World Congress
on Electrical Engineering and Computer Systems and
Science (EECSS'17) Rome.
COST Action 231. (1999). Digital Mobile Radio Towards
Future Generation Systems – Final Report. European
Communities, Luxembourg.
M. Pinem and R. Fauzi. (2018). The effect of various
parameters of large scale radio propagation models on
improving performance mobile communications. IOP
Conf. Ser. Mater. Sci. Eng., vol.309, no. 135, p. IOP
Publishing.
Maksum Pinem. (2014). Optimization of Performance
parameter of CDMA System by Using Empirical
Radio Wave Propagation Channel. Disertation,
University of North Sumatera.
Maksum Pinem, et al. (2018). Characterization of Outdoor
to Indoor Propagation in Urban Area by Using A
Combination of COST231 Walfisch-Ikegami and
COST231 Multiwall Models in 1800 Mhz and 2100
Mhz. International Journal of Engineering &
Technologi (IJET), Vol 7, No 3.2, pp.: 698-702.
Nining Triana. (2015). Analysis of Semi-Deterministic
Path Loss Propagation Model For Triple Band
Applications in Metropolitan Area. Singuda Ensikom
Journal Department of Electrical Engineering.
University of North Sumatera.
O.O. Oni and F.E. Idachaba. (2017). Review of Selected
Wireless System Path loss Prediction Models and its
Adaptation to Indoor Propagation Environments.
Proceedings of the International Multi Conference of
Engineers and Computer Scientists, Vol II. Hongkong
Another reference.
Singh, N. P and Singh, B. (2010). Performance
Enhancement of Cellular Network Using Adaptive
Soft Handover Algorithm. Wireless Personal
Communications.
Parameter Analysis of Semi Deterministic Pathloss against Soft Handover Performance in Mobile Communication
247
