Overview of Propagation Models for Mobile Communication
In this world we are all
connected by Wireless Communication. We all know how mobile communication plays
an important role in our day-to-day life. There are various propagation models
for mobile communication. Explosive growth of mobile communication continues, it
is very valuable to have the capability of determining optimum base-station locations
,obtaining suitable data rates and estimating their coverage ,without
conducting a series of propagation measurement, which are very expensive and
time consuming. It is therefore important to develop effective propagation
models for mobile communication.
Propagation or Path loss
models are basically used to predict coverage area, frequency assignment and
interference, which are the main concerns in cellular network planning.
The path loss values compared
with existing model for rural, suburban and urban areas. The propagation model
tuning must optimize the model parameters in order to achieve minimal error
between predicted and measured signal strength.
PATH
LOSS:
Ratio of the transmitted
power to the received power is the Path Loss between a pair of antennas,
usually expressed in decibels(dB). All the possible loss elements associated
with interaction between propagating wave and objects in between transmitter
and receptor antenna are included in Path Loss of antenna.
In
mobile channels Path Loss applies to the power averaged over several
fading cycles. This pathloss is difficult to measure directly as various losses and gains in the
radio system also have to be considered.
To define pathloss very
properly the losses and gain in the system must be considered.
[1]
The power PR appearing at the receiver input
terminals of the antenna can be expressed as
PR = PTGTGR/LTLLR
Where,
PR= received power
PT= transmit power
GT= transmitting antenna gain
GR= receiving antenna gain
L= Path Loss
LT=transmitting feeder loss
LR=received feeder loss.
EIRP(effective isotropic radiated power) = PTGT/LT
PTI = effective isotropic transmitting
power
PRI = effective isotropic receiving power
PRI = PR LR/ GR
The advantage of
expressing the powers in terms of EIRP is that the path loss L, can then be
expressed independently of system parameters by defining it as the ratio
between the transmitted and the received EIRP, or the loss that would be
experienced in an idealized system where the feeder losses, were zero and the
antennas were isotropic radiators( GT,R =1, LT,R =1 ).
Main goal of propagation model is to predict the Path
Loss as accurately as we possible.
L= PTI /PRI = PTGTGR/PRLTLR
The maximum range of the system
occurs when the received power drops below a level which provides just
acceptable communication quality. This level is often known as the receiver
sensitivity. The value of L for which this power level is received is the
maximum acceptable path loss. It is usual to express the path loss in decibels,
so that
LdB=10 log (PTI / PRI)[1]
PROPAGATION
MODELS:
To predict the
propagation loss for mobile let us go through some Path Loss model. Path loss
models are very important in wireless cellular systems.
[1]
FREE SPACE MODEL:
In this model pathloss L[1] defines the loss during propagation from transmitter to receiver. This model is diverse on frequency and distance where Frequency f is calculated in MHz and distance d is in Km. It can be calculated as
In this model pathloss L[1] defines the loss during propagation from transmitter to receiver. This model is diverse on frequency and distance where Frequency f is calculated in MHz and distance d is in Km. It can be calculated as
L
= 32.45 + 20log ( d) + 20log (f)
· HATA-OKUMUA MODEL:
To make the traditional okumura’s model easier
for computer implantation Hata’s model delivered from okumura and has fit
okumura’s curves with analytical expression , because of this computer
implementation of this hata-okumura model is straightforward. The formula for
the median path loss in urban areas
is given by
L( urban) = 69.55 + 26.16logf
-13.S2loghte-ahre + (44.9 -6.55 loghte) log d
frequency (in MHz), which varies from
150 -1500 (MHz),
hte and hre are
the effective heights of the base station and the mobile antennas (meters)
respectively
d is the distance from the base
station to the mobile antenna
a(hre) is the correction
factor for the effective antenna height of the mobile unit, which is a function
of the size of the area of coverage.
For small to medium-sized cities, the mobile-antenna correction factor is given
by
a(hre) = (1.1 logf -0.7)hre
-(1.56 logf -O.8)
For a large city, it is given by
a(hre)= { 8.29(log(1.54 hre))2
-1.1 , f < 300MHz
3.2(log(l1.75hre))2
-4.97 , f >= 300MHz
To
obtain the path loss in a suburban area,
the standard Hata formula is
L50 (dB) = L50(urban )-2[log(f/28)]2
-5.4
The path loss in open rural areas is expressed through
L50(dB) = L50
(urban) -4.78(log f)2 -18.33 logf -40.98
Today, the Hata implementation of the Okumura's model
can be found in almost every RF propagation.
· COST
– 231 HATA MODEL:
COST -231 Hata model is widely used for predicting
path loss in mobile wireless system. This model was devised as an extension to
the Hata-Okumura model. The model is designed to be used in the frequency band
from 500 MHz to 2000 MHz. This model also contains corrections for urban,
suburban and rural (flat) environmental conditions.
The basic equation for path loss in dB is [4]:
L50 (dB) = 46.3 + 33.9logf - 13.82loghb
+cm – ahm + (44.9 - 6.55loghb)logd
where, f: frequency (MHz)
d: distance
from the base station to the mobile antenna in (km)
hb
is the base station antenna height above ground level in metres.
The parameter cm is defined as 0dB for
suburban or open environments and 3dB for urban environments. The parameter ahm
is defined for urban environments as [6]:
ahm = 3.2(log(11.75hr))2
- 4.97 ,f > 400Mhz
For suburban or rural (flat) environments, the
parameter is defined as:
ahm = (1.1logf - 0.7)hr - (1·56logf-0.8)
where, hr: mobile antenna height above ground level.
This model is quite suitable for large-cell mobile
systems, but the model requires that the base station antenna to be higher than
all adjacent rooftop.
·
STANFORD UNIVERSITY INTERIM (SUI)
MODEL:
IEEE
802.16 is a series of wireless broadband standards written by the Institute of
Electrical and Electronics Engineers (IEEE). The working group proposed the
standards for the frequency band below 11 GHz containing the channel model
developed by the Stanford University, namely the SUI models. This prediction
model also came from the extension of Hata model with frequency larger than
1900 MHz. The correction parameters are allowed to extend this model up to 3.5
GHz band. In the United States of America, this model is defined for the
Multipoint Microwave Distribution System (MMDS) for the frequency band from 2.S
GHz to 2.7 GHz.
The base station
antenna height of SUI model can be used between 10 m to 80 m. Receiver antenna
height varies from 2 m to 10m. The cell radius varies between 0.1 km to 8 km.
The SUI model describes three types of terrain, they are terrain A, terrain B
and terrain C. Terrain A can be used for hilly areas with moderate or very
dense vegetation. This terrain presents the highest path loss. In this blog, we
consider terrain A as a dense populated urban area. Terrain B is characterized
for the hilly terrains with rare vegetation, or flat terrains with moderate or
heavy tree densities. This is the intermediate path loss scheme. We consider
this model for suburban environment. Terrain C is suitable for flat terrains or
rural with light vegetation, here path loss is minimum.
The basic path loss
expression of The SUI model with correction factors is presented as [7]:
L = A +
10γlog(d/d0) + Xf + Xh + s for d>
d0
Where, d: distance between base station and
mobile antenna in (metres)
d0:
100m
Xf
: correction for frequency above 2GHz in (MHz)
Xh
: correction for receiving antenna height
s:
correction for shadowing in dB
γ:
path loss exponent
The random variables in the formula are taken through
a statistical procedure. The log normally distributed factor s is between 8.2
dB and 10.6 dB for shadow fading because of trees and other clutter on a
propagations path. The parameter A is defined as:
A = 20 log( 4πd0/lambda )
and the path loss exponent γ is given by:
γ = a – bhb
+ (c/hb)
where, the parameter hb is the base station
antenna height in meters and ranges between 10 m and 80 m. The constants a, b,
and c depend upon the types of terrain, that are given in Table 2[1].
The frequency correction
factor Xf and the correction for receiver antenna height Xh
for the model are expressed in:
Xf = 6.0 log(f/ 2000)
Xh = -10.8
log(hr/2000) for terrain type
A and B
Xh = -20.0
log(hr/2000) for terrain type
C
where, f is the operating frequency in MHz, and
hr is the receiver antenna height in metres.
For the above correction
factors this model is extensively used for the path loss prediction of all
three types of terrain in rural(C), urban(A) and suburban(B) environments.
Sr. No.
|
Model Parameter
|
Terrain A
|
Terrain B
|
Terrain C
|
1
|
a
|
4.6
|
4
|
3.6
|
2
|
b
(m^-1)
|
0.0075
|
0.0065
|
0.005
|
3
|
C(m)
|
12.6
|
17.1
|
20
|
· ECC-33
MODEL:
The
original Okumura model’s experimental data were gathered in the suburbs of
Tokyo[6] . The authors in the research papers refer to urban areas subdivided
into 'large city' and 'medium city' categories. They also give correction
factors for 'suburban' and 'open' areas. Use of ‘medium city model’ is recommended
for European cities. Although the Hata-Okumura model is widely used for UHF
bands, its accuracy is questionable for higher frequencies. The COST-231 model
was extended to use up to 2 GHz but it was proposed for mobile systems having
omnidirectional receiver antennas sited less than 3 m above ground level.
A
different approach was considered, which extrapolated the original measurements
by Okumura and modified its assumptions so that it more closely represents a
wireless system. This path loss model is referred as the ECC-33 model.
The
path loss is defined as:
L
= Afs + Abm – Gb - Gr
where,
Afs , Abm , Gb and Gr are the free
space attenuation, the basic median path loss, the Base station height gain
factor and the receiver height gain factor respectively.
They are individually defined as the
following:
Afs
= 92.4 + 20 log d + 20 log f
Abm
= 20.41 + 9.83logd + 7.89logf +9.56[logf]2
Gb
= log(hb/200)(13.958 + 5.8log(d))2
For
medium city environment ,
Gr
= [42.57 + 13.7logf][log(hr)-0.585]
and
for large city Gr = 0.759 hr
- 1.862
where, f is the frequency
in GHz
d
is the distance between base station and mobile antenna in km
hb
is the base station antenna height in metres and
hr
is the mobile antenna height in metres
The medium city model is more appropriate for
European cities whereas the large city environment should only be used for
cities having tall buildings like sky scrapers. It is interesting to note that
the predictions produced by the ECC-33 model do not lie on straight lines when
plotted against distance having a log scale.
·
STANDARD MACRO-CELL MODEL:
This
model is an empirical model based on the modified Hata model. Before going into
the details of the model, lets first understand what is macro cell. The cell is
the area in which a bandwidth of frequency is being used for mobile
communication. Macro cell is a widest
range of cell sizes. (around 35 km wide) and it provides high power transmission.
As the number of users per area increases, macro cell is further get divided
into microcells(2 km wide), picocells(up to 200 m wide) and femtocells(10 m).
Standard Macro-cell Model is used for macro cells and
it is usually used in rural areas where number of users per area are less or
along the highways where continuous handoff is unnecessary. In this model,
three main factors are taken into consideration.
1. Effective
base station height
2. Diffraction
loss
3. Effects
of clutter
To measure the diffraction loss, the Epstein-Peterson,
Bullington, Deygout or Japanese Atlas knife edge techniques are used.
The formula for the path loss in this model is given
as[2],
Where,
[3]
The
propagation model can be further tuned by modifying the k factors. For improved
near and far performance, dual slope attenuation can be introduced by
specifying both near and far values for k1 and k2.
·
LOG
DISTANCE PROPAGATION MODEL:
This model is based on the theory
that, the average received signal power decreases logarithmically with distance
(d) between the transmitter and the receiver.
This can be
mathematically expressed as,
Where,
[3]
Here, n gives the idea of
size of obstructions. Larger the n, a greater number of obstructions are
present in the path hence the decrease in average received power is faster as
distance become larger.
Also, the reference
distance 
varies
according to the propagation environment. In large coverage cellular
systems, 1 km reference distances are commonly used and in microcellular
systems, much smaller distances (such as 100 m or 1 m) are used. The reference
distance should always be in the far field of the antenna so that near-field
effects do not alter the reference path loss.
varies
according to the propagation environment. In large coverage cellular
systems, 1 km reference distances are commonly used and in microcellular
systems, much smaller distances (such as 100 m or 1 m) are used. The reference
distance should always be in the far field of the antenna so that near-field
effects do not alter the reference path loss.
· BERTONI-WALFISCH
PROPAGATION MODEL:
This model is a
semi-empirical model. It is applicable for propagation through buildings in
urban environments. This model is known for its simplicity and validity. This
model works on some assumptions, they are:
· Heights
of buildings are to be uniformly distributed.
· Separation
between buildings are equal.
Then, the model
considers the multiple diffraction past these rows of buildings.
Where,
·
[3]
We have discussed different propagation models up till
now in the blog. Selection of propagation model changes according to the geographical
area in which it has to be applied or implemented. This can be illustrated by
some following experiments performed at different locations.
Ø
Dar
es Salaam names city which is located in
Tanzania is chosen for comparison of different propagation model. For
presenting urban area, Posta (NIC) were selected ,for suburban part Kizuiani were
chosen and for rural part Kimbiji was selected.
Experimental meausrements are taken in these 3 areas for 2G/3G system. Experimental
measurements of radio propagation characteristics are made in urban, suburban
and rural areas for a 2G/3G system working at 900/1800/2100 MHz frequencies.
Comparison
of error standard deviation is shown in the below table.
Sr. No.
|
Error
Standard Deviation
|
Hata
|
ECC
|
SUI
|
Ericsson
|
COST 231
|
1
|
Urban
|
17.68
|
25.98
|
15.92
|
25.84
|
12.98
|
2
|
Suburban
|
28.47
|
14.50
|
37.67
|
31.91
|
18.88
|
3
|
Rural
|
37.89
|
NA
|
10.99
|
43.94
|
11.22
|
From
above table we can observe that no model is perfectly suitable for all the
three regions. From above table, COST 231 has minimum error standard deviation
i.e. 12.98 for urban area among all the models. Similarly ECC has least value
i.e. 14.50 for suburban area and SUI has least value i.e. 10.99 for rural area.
But COST 231 Hata model has the least average error standard deviation for the
three environments. i.e. each model works differently for particular area.
Here
are some graphs showing the relation between pathloss and the distance for
different models in urban, suburban and rural areas respectively.
Fig.
Comparison of path loss models
with the measurement from urban area
Fig.
Comparison of path loss models
with the measurement from suburban area
Fig.
Comparison of path loss models
with the measurement from rural area.
From these graphs
also we can observed that each propagation model works differently in different
areas with different efficiencies.
Ø
Another
two experiments were done on the same city called Nablus which is in Palestine[3].
For
the first experiment, cusing digital maps city was classified into buildings,
low tree, buildings, agriculture, seasonal water bodies. Parameters for network designing such as coverage,
capacity and quality of service were considered for the network design for the
city For cell planning, radio cell planning tool is used to predict the radio
coverage by means of propagation models, for a particular area.
From
the simulation result, they selected Algorithm 9999 model which is dependent on
the Ericsson mand Okumura – Hata model
as best suited .
For the second experiment done on the same city,
geographical structure like buldings, mountains were considered. By applying
different empirical propagation models such as Bertoni-Walfisch, Hata, Haret,
standard macrocell model, log distance propagation model, COST231 Walfisch-
Ikegami , different parameters such as mean error, standard deviation etc. are
calculated.
Comparsion
of these models on the basis of above mentioned parameter is shown in the
following table.
Sr.
No.
|
Empirical
Propagation Model
|
Mean
Error (dB)
|
Standard
Deviation
|
Root
Mean Square Error
|
1
|
Hata
|
12.598
|
12.96
|
18.075
|
2
|
Haret
|
10.348
|
12.98
|
16.6
|
3
|
COST
231 Walfisch-Ikegami
|
10.58
|
12.99
|
16.76
|
4
|
Bertoni-
Walfisch
|
1.426
|
13
|
13.07
|
From the above table it is seen that Bertoni- Walfisch
model has least mean error and root mean square error. So this was the best
model for the city in this experiment.
Statistics & Result about the
different Propagation Models and their comparison:
STANDARD MACROCELL MODEL TUNING:
As it is a emperical model the tuning of the model can
be done by various methods after the tuning of the Standard Macrocell Model the
coefficients ,K1 and K2 are changed .The tuning of trhe model was done by the LMSE
on the path loss equation .
Pl(dB)=k1+k2log(d)+k3(Hms)+k4log(Hms)+k5log(Heff)+k6log(Heff)log(d)+k7(diffin)+Closs
The pathloss in the Standard Macro cell Model before
tuning and after tuning is represented in the figure.
Parameters
|
Before Tuning
|
After
Tuning
|
K1
|
135
|
139.41
|
K2
|
38
|
30
|
K3
|
-2.55
|
|
K4
|
0
|
|
K5
|
-13.82
|
|
K6
|
-6.55
|
|
K7
|
0.7
|
|
fig. Path loss comparison of Standard Macrocell model before and after tuning
BERTONI-WALFISCH MODEL TUNING:
Also Bertoni-Walfisch model is a empirical model the
tuning of the model can be done by various methods after the tuning of the
Bertoni-Walfisch Model the coefficients
Pl(dB)=78.5+A+23log(d)-18log(ht-hb)+21log(f)
The
Path loss before tuning and after tuning is given in the graph given below.
Before Tuning
|
After Tuning
|
89.5
|
78.5
|
38
|
23
|
2
|
21
|
fig. Path loss comparison of Bertoni-Walfisch model before after before tuning
Mean Error comparison between tuned
Bertoni-Walfisch model with known Models
BS#
|
Tuned
Bertoni-Walfisch
|
Bertoni-Walfisch
|
Hata
|
Walfisch-Ikegami
|
Haret
|
Standard
Macrocell Model
|
BS1
|
0
|
1.426
|
12.59
|
10.58
|
10.34
|
10.91
|
BS2
|
6.978
|
10.728
|
17.82
|
16.5
|
10.32
|
18.536
|
BS3
|
2.367
|
9.633
|
9.737
|
10.106
|
8.636
|
12.067
|
BS4
|
3.254
|
6.941
|
14.72
|
11.697
|
10.96
|
14.510
|
BS5
|
10.041
|
12.32
|
23.11
|
18.936
|
15.76
|
21.774
|
BS6
|
3.342
|
11.576
|
10.789
|
11.083
|
9.707
|
13.565
|
BS7
|
5.88
|
8.991
|
16.424
|
14.322
|
13.567
|
16.797
|
BS8
|
16.813
|
16.311
|
27.21
|
25.255
|
24.377
|
25.971
|
Avg Mean Error
|
6.64
|
9.55
|
16.55
|
14.80
|
12.96
|
16.76
|
Ref #[3] Allam Mousa, Y. D. (2012). Optimizing Outdoor Propagation Model based on Measurements for Multiple RF Cell
Standard Deviation comparison between tuned Bertoni-Walfisch model with known Models
BS#
|
Tuned Bertoni-Walfisch
|
Bertoni-Walfisch
|
Hata
|
Walfisch-Ikegami
|
Haret
|
Standard Macrocell Model
|
BS1
|
11.294
|
13
|
12.96
|
12.99
|
12.98
|
11.792
|
BS2
|
9.544
|
13.52
|
12.73
|
13.52
|
12.879
|
10.807
|
BS3
|
7.956
|
8.941
|
8.861
|
8.94
|
12.358
|
8.396
|
BS4
|
9.2
|
11.362
|
11.163
|
11.362
|
11.362
|
10.157
|
BS5
|
9.09
|
10.987
|
10.567
|
10.987
|
10.644
|
9.621
|
BS6
|
5.127
|
6.027
|
5.944
|
6.026
|
5.924
|
5.496
|
BS7
|
8.039
|
9.286
|
9.220
|
9.286
|
9.229
|
8.556
|
BS8
|
7.559
|
8.538
|
8.489
|
8.538
|
8.496
|
7.987
|
Avg
Mean Error
|
8.47
|
10.20
|
9.99
|
10.20
|
10.48
|
9.10
|
Ref #[3] Allam Mousa, Y. D. (2012). Optimizing Outdoor Propagation Model based on Measurements for Multiple RF Cell
Path Loss Comparison Between :
· Hata
Model
· Bertoni-Walfisch
model before tuning
· Haret
Model
· Malfisch-Ikegami
model
· Standard
Macrocell model
· Bertoni-Walfisch
model after tuning
fig. Path loss comparison of different models
Conclusion:
In this blog we have discussed various propagation
model namely Bertoni-Walfisch, Standard macrocell model, Log distance
propagation model, Hata okumura model, Ecc-33 model, Stanford
university interim (SUI) model, Cost 231 Hata model. The statistics and the
data collected from the various resources confirms that according to the urban,
suburban, rural area terrain the various models can be implemented. Although,
when it comes to generalization of which model is most dominating, no model
outperforms all other model in all conditions. Each model differs widely in approach
of complexity and accuracy. Most cellular operator use version of Hata model
for conducting propagation characterization. Also the survey which was carried
out in the nabukus city of palestine. After the tuning of Bertoni-Walfiesch model, it really stood up.
[2].Tarapiah, S. a.
(2016, July). Mobile Network Planning Process Case Study - 3G network. Computer
and Information Science, 9, 115. doi:10.5539/cis.v9n3p115.
[3] Allam Mousa, Y. D.
(2012). Optimizing Outdoor Propagation Model based on Measurements for Multiple
RF Cell. International Journal of Computer Applications (0975 – 8887) , Volume
60– No.5, 6.
[4] C.
Action, "231," Digital Mobile Radio Towards Future Generation
Systems, Final Report". European Cooperation in the Field of Scientific
and Technical Research, EUR, vol. 18957, 1999.
[5]Y. Okumura, E. Ohmori,
T. Kawano, and K. Fukuda, "Field strength and its variability in VHF and
UHF land-mobile radio service," Rev. Elec. Commun. Lab, vol. 16, pp.
825-73, 1968.
[6] H. R. Anderson, Fixed
Broadband WirelessSystem Design: John Wiley & Sons, 2003. V.
[7 ] Abhayawardhana, 1.
Wassell, D. Crosby, M. Sellars, and M. Brown, "Comparison of empirical
propagation path loss models for fixed wireless access systems," in
Vehicular Technology Conference, 2005. VTC 2005-Spring. 2005 IEEE 6lst, 2005,
pp. 73-77. S
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