17022-CHIBUZO_ _BULG__    PROM_Parametric  Analysis Of Isolated Doubled Edged Hill Diffraction (1)


 217 

Mathematical and Software Engineering, Vol. 3, No. 2 (2017), 217-225. 
Varεpsilon Ltd,  varepsilon.com 

 
Parametric Analysis of Isolated Doubled Edged 
Hill Diffraction Loss Based on Rounded Edge 

Diffraction Loss Method and Different Radius of 
Curvature Methods 

 
Mfonobong Charles Uko1, Uduak Etim Udoka1, and 

Chibuzo Promise Nkwocha2* 

 
*Corresponding Author: chibuzorpromise525@yahoo.com 
1Department of Electrical/Electronic and Computer Engineering, University of Uyo, Uyo, 
Nigeria 
2Department of Chemical Engineering  Federal University of Technology, Owerri 

(FUTO), Owerri, Nigeria 
 

Abstract 
In this paper, parametric analysis of isolated doubled edged hill diffraction loss based 

on rounded edge diffraction loss method is presented. Particularly, the variation of the 
diffraction loss due to changes in frequency and radius of curvature of the rounded edge of 
isolated doubled edged hill obstruction are studied. Also, the ITU-R P.526-13 rounded edge 
diffraction method is used to compute the diffraction loss. However, the radius of curvature 
is computed using two approaches, namely, the ITU-R P.526-13 method and the occultation 
distance based method. The results show that the rounded edge diffraction computed based 
on the  ITU-R P.526-13  radius of curvature method is much higher than the one 
computed with the occultation distance based radius of curvature approach. At frequency of 
1 GHz, the percentage difference in diffraction loss  is about 29 % and the difference 
increases with frequency to as high as 74.5 % at 36 GHz. Similarly, the ITU-R P.526-13 
radius of curvature is extremely higher than the occultation distance based radius of 
curvature. At frequency of 1 GHz, the percentage difference in radius of curvature  is 
about 218 % and the difference increases with frequency to as high as 395 % at 36 GHz. In 
view of the results, the ITU-R P.526-13 radius of curvature method should be reviewed to 
ascertain the specific conditions it can be employed. 

 
Keywords: Radius of Curvature; Rounded Edge Obstruction; ITU 526-13  Method; 

Occultation Distance; Double Edged Hilltop; Single Edged Hilltop; Fresnel 
Zone; Radius of Fresnel Zone. 

1. Introduction 
Diffraction loss caused by obstruction is one of the components of path losses 
considered in the design of wireless network [1-9]. Particularly, in line-of-sight 
communication links it is required that at least 60% clearance be maintained with 
respect to the first Fresnel zone [10-14]. As such, experts have developed different 
methods for the determination of the diffraction caused by different kinds of obstruction. 
In most cases, isolated obstructions are modeled as knife edge obstruction [15-19]. 
However in reality , obstructions are much more complex than the knife edge 
obstruction model. Besides, the knife edge model tends to under estimate the diffraction 



 218 

loss some cases. Consequently, the rounded edge diffraction model was introduced by 
expert to account for extra diffraction loss that real obstructions present beyond the 
values obtained through the knife edge model [20-21]. 

 In order to determine the diffraction loss due to rounded edge, the radius of curvature 
or the rounded edge is first determined. Accordingly, the International 
Telecommunication Union (ITU) has developed the ITU-R P.526-13 method for 
computing the radius of curvature for rounded edge diffraction loss computation [22]. In 
the ITU-R P.526-13 method the radius of the first Fresnel zone is used to determine the 
portion of the obstruction profile that will be used in the determination of the radius of 
curvature [22-25]. Consequently, for a given obstruction, with the ITU-R P.526-13 
method the radius of curvature varies with frequency since the radius of the Fresnel 
zone is a function of frequency. However, with another method that is based on the 
occultation distance [26-27], the radius of curvature does not vary with frequency. 

Generally, the radius of curvature affects the value of rounded edge diffraction loss. In 
this paper, the effect of radius of curvature on diffraction loss over isolated doubled 
edged hill is studied. The ITU-R P.526-13 method gives large values of radius of 
curvature as the occupation distance of the obstruction increases. Double edged hill tend 
to have larger occultation distance. As such, this paper seeks to examine the impact of 
the radius of curvature on the diffraction loss over isolated doubled edged hill with 
relatively large occultation distance. Sample elevation profile of double edge hill is used 
in this paper and the analysis is performed for different frequencies in the various 
microwave frequency band. The diffraction loss results are compared for the two 
methods of computing the radius of curvature, namely, one based on the ITU-R 
P.526-13 method and the other on the occultation distance. 

2. Theoretical Background 

2.1 The Path Profile and Double Edged Hill Obstruction Geometry  
Path profile for a line of sight (LOS) link with double edged hill obstruction is shown in 
Figure 1  In Figure 2 , a rounded edge of radius, R is fitted in the vicinity of the double 
edged hilltop. Tangent line referred to as Tangent 1 is drawn from the transmitter to the 
path profile at point T1 . Another tangent line referred to as Tangent 2 is drawn from the 
receiver to the path profile at point T2 and extended to intersect the Tangent T1 above the 
hill vertex. The LOS clearance , h is the height from the LOS to the point of intersection 
of Tangent 1 and tangent 2, as shown in figure 2 . The occultation distance , D of the 
obstruction is the distance between T1 and T2. The angle Tangent 1 makes with the LOS 
is denoted as α� while the angle Tangent 2 makes with the LOS is denoted as α�. The 
angle the LOS makes with the horizontal is denoted β. 

 
Figure 1: The path Profile Plot Of The Double Edged Hill 



 219 

 
Figure 2: The Path Profile and Double Edged Hill Obstruction Geometry 

As shown in figure 2 , ��   is distance from the transmitter to the point where the 
LOS clearance is measured and ��   is distance from the receiver to the point where 
the LOS clearance is measured. Let d be the distance between the transmitter and the 
receiver, then: 

	d = d� + d�   (1) 
From figure 2 , β which is the angle the  LOS   makes with the horizontal is given as: 

β =	
��
� ���
��� �  (2) 
where 

H� is the height of the transmitter and H�  is the height of the receiver and d is the 
distance between the transmitter and the receiver. The values of d, H� and H�  are 
obtained from the path profile data. 

In Figure 2,  α� is the angle (in radian)  between the LOS and  tangent 1  and   α� is  the angle (in radian)  between the LOS and  tangent 2.   Then,  α is the 
external angle (in radian)   between tangent 1 and tangent 2 at their point of 
intersection above the hill vertex, where  

  	α = α� + α�       (3) 
The angles α� and α� are obtain by cosine rule as follows: 

Cos�� = ����
�������
�����
���������   (4) 

α� = Cos
� �����
�������
�����
��������� � (5) 

Similarly,  

α� = Cos
� �����
�������
�����
��������� � (6) 

where S� is the length of the tangent 1  measured from the transmitter to the point of 
intersection of tangent 1 and tangent 2, as shown in Figure 2. 

S� is the length of the tangent 2  measured from the receiver to the point of intersection 
of tangent 1 and tangent 2, as shown in Figure 2. 



 220 

S  is the length of the LOS measured from the transmitter to receiver 
S�,	S�	 and S  are in meter and they are measured out from the path profile plot and the 
tangent line drawn on the path profile. 

The line of sight(LOS) clearance, h is given as; 

h =	��"�#$�%��&�#$�'(
)� 	  (7) 
The diffraction parameter, ν   is given as: 

v = ℎ,��-��-��.�-���-��   (8) 
where ʎ is the signal wavelength  which is given as:  

				ʎ	 = 01	    (9) 
f is the frequency in Hz and c is the speed of light which is 3x104 m/s. 

2.2 The Rounded edge  diffraction loss by ITU-R P.526-13 Method 
The diffraction loss for single rounded obstacle according to Recommendation ITU-R 
P.526-13 may be calculated as [22]: 

A-6 = 7�ν� + T�m,n�	  (10) 
where:   J(ν) is the Fresnel-Kirchhoff loss due to an equivalent knife-edge placed with 
its peak at the vertex point. The diffraction parameter ν may be evaluated as given earlier 
in Eq 3.15.  where h and λ are in meters, and d1 and d2 are in kilometres. The knife edge 
diffraction loss , J(ν) may be obtained according to ITU –R 526 where it is as given earlier 
in Eq 3.17. T(m,n) is the additional attenuation due to the curvature of the obstacle and it 
is given as [22]: 

=>?	@� ≤ 4 
T�m,n�dB	 = 	7.2�@��/� − �2 − 12.5��@ + 3.6�@� /� − 0.8�@��	         (11) 

=>?	@� > 4 
	T�m,n�	dB =	−6 − 20N>O�@�� + 7.2�@��/� − �2 − 17��@ + 3.6�@� /� −

0.8�@��			(12) 
m = P�

�Q�RQ��
	�Q���Q���
ST�U�V W

�/� 	         (13) 

� = XS
T�U�
V W
Y

�/ 
	         (14) 

2.3 The Radius Of Curvature For The Rounded Edge Diffraction 
Computation 

2.3.1 The Occultation Distance Based Radius Of Curvature For The 
Rounded Edge Diffraction Computation  

The occultation distance-based method for computing the  radius of curvature for the 
rounded edge obstruction  is given as follows [26-27]: 

Z =	 ��[��-���-���%�"�-�����-���&	  (15) 
where D is the occultation distance and it is obtained from the graph plot of the path 
profile  and geometry of the obstruction, as shown in figure 2 .  Particularly, a line 



 221 

(referred here as tangent 1) is drawn from the transmitter to be tangential to the path 
profile at the vicinity of the hill apex. Let the tangent point of tangent 1 with the path 
profile be denoted as T1. Again, another line (referred here as tangent 2) is drawn from 
the receiver to be tangential to the path profile at the vicinity of the hill apex . Let the 
tangent point of tangent 1 with the path profile be denoted as T2. Then, D is the distance 
between T1 and T2. The point at which the tangent 1 and tangent 2 intersect above the 
hill vertex, as shown in figure 2 . 

2.3.2 The ITU Radius Of Curvature Method For The Rounded Edge 
Diffraction Computation  

According to ITU-R 526-13 method for computing the  radius of curvature for the 
rounded edge obstruction  is given as follows [22];  

?\ =	 ]^	
�

��_^	�     (16) 
where   ?\ is the radius of curvature corresponding to the sample i of the vertical 
profile of the ridge in figure 3. 

 
Figure 3: The Geometry of the Vertical Profile of the obstruction used for the 
determination of the radius of the rounded edge fitted to the vicinity of the 
obstruction vertex according to ITU Method [22]. 

When fitting the parabola, the maximum vertical distance from the apex to be used in 
this procedure should be of the order of the first Fresnel zone radius where the obstacle 
is located.  As such, in figure 3, the maximum `\	is less or equal to the  radius of first 
Fresnel zone at the  point of maximum elevation.  In the case of N samples, the median 
radius of curvature of the obstacle is denoted as R where [22]: 

Z =	∑ �?\�\bc\b� =	∑ � ]^	
�

��_^	��
\bc\b�     (17) 

According to the ITU-R 526-13 recommendation, from the  obstruction apex  (in 
Figure 2)  the maximum value of `\	should be within the radius of the first Fresnel 
zone denoted as �d�. Essentially; 

 @�ef@g@�`\�	≤ �d�	  (18) 
The radius of the first Fresnel zone (r�)  at distance  	��   from the transmitter and �� 
from the receiver is given as: 

r� 	= ,	iʎ���			����	�j���				�	��		�       (19) 



 222 

where ʎ is the signal wavelength.  which is given as				ʎ	 = 01	   (20) 
f is the frequency in Hz and c is the speed of light. 

3. Results and Discussions 
Sample numerical example is conducted   based on path profile of  microwave link 
with isolated  double edged hilltop shown in Table 1. Microwave frequencies from   1. 
GHz in the L-band   to 36GHz in the Ka-band are considered. 

Table 1:  The path profiles data for the of  microwave links   with isolated  double 
edged hilltop 
Distance 
(m) 

Elevation 
(m) 

Distance 
(m) 

Elevation 
(m) 

Distance 
(m) 

Elevation 
(m) 

Distance 
(m) 

Elevation 
(m) 

Distance 
(m) 

Elevation 
(m) 

0.0 405.6 1595.3 394.4 3190.5 416.3 4785.8 426.5 6381.0 381.6 

53.2 405.6 1648.4 392.6 3243.7 411.9 4838.9 427.3 6434.2 382.1 

106.4 405.6 1701.6 391.9 3296.9 416.5 4892.1 427.1 6487.4 382.6 

159.5 405.4 1754.8 391.0 3350.0 418.5 4945.3 426.4 6540.5 382.7 

212.7 405.4 1808.0 389.7 3403.2 416.5 4998.5 426.7 6593.7 382.7 

265.9 405.5 1861.1 388.6 3456.4 416.9 5051.6 426.4 6646.9 382.7 

319.1 405.5 1914.3 388.1 3509.6 423.5 5104.8 422.1 6700.1 382.7 

372.2 405.1 1967.5 387.6 3562.7 423.5 5158.0 395.4 6753.2 383.1 

425.4 404.3 2020.7 387.6 3615.9 426.5 5211.2 394.9 6806.4 383.7 

478.6 403.0 2073.8 387.3 3669.1 425.5 5264.3 393.9 6859.6 384.0 

531.8 402.2 2127.0 396.7 3722.3 426.3 5317.5 392.5 6912.8 384.0 

584.9 401.5 2180.2 396.2 3775.4 427.1 5370.7 391.5 6965.9 383.5 

638.1 401.3 2233.4 395.8 3828.6 426.6 5423.9 390.7 7019.1 382.9 

691.3 401.3 2286.5 395.1 3881.8 427.1 5477.0 389.5 7072.3 382.6 

744.5 401.0 2339.7 393.7 3935.0 427.1 5530.2 388.1 7125.5 382.6 

797.6 400.7 2392.9 393.7 3988.1 427.4 5583.4 387.0 7178.6 383.3 

850.8 400.3 2446.1 395.9 4041.3 426.3 5636.6 386.1 7231.8 382.2 

904.0 399.9 2499.2 398.7 4094.5 425.2 5689.7 385.8 7285.0 381.5 

957.2 399.7 2552.4 402.1 4147.7 425.6 5742.9 385.7 7338.2 381.0 

1010.3 400.0 2605.6 398.5 4200.8 423.9 5796.1 385.3 7391.3 381.0 

1063.5 400.2 2658.8 401.8 4254.0 423.1 5849.3 384.8 7444.5 381.0 

1116.7 400.3 2711.9 400.2 4307.2 423.6 5902.4 384.0 7497.7 380.9 

1169.9 399.3 2765.1 402.2 4360.4 423.3 5955.6 383.0 7550.9 381.8 

1223.0 398.0 2818.3 404.0 4413.5 423.4 6008.8 382.3 7604.0 380.6 

1276.2 395.6 2871.5 405.7 4466.7 423.5 6062.0 381.4 7657.2 381.5 

1329.4 392.5 2924.6 407.5 4519.9 425.6 6115.1 380.6 7710.4 382.4 

1382.6 391.6 2977.8 410.7 4573.1 424.9 6168.3 380.2 7763.6 383.2 

1435.7 390.7 3031.0 411.5 4626.2 426.8 6221.5 380.5 7816.7 385.5 

1488.9 389.7 3084.2 413.0 4679.4 426.6 6274.7 380.9 7869.9 385.5 

1542.1 388.7 3137.3 414.9 4732.6 426.6 6327.8 381.1 7923.1 385.5 

 



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Table 2 shows the diffraction loss, radius of curvature and radius of Fresnel zone 
for different frequencies and radius of curvature methods. According to the results in 
Table 2, the rounded edge diffraction computed based on the  ITU-R P.526-13  radius 
of curvature is much higher than the one computed with the occultation distance based 
radius of curvature. At frequency of 1 GHz , the percentage difference in diffraction loss 
(%) is about 29% and the difference increases with frequency to as high as 74.5% at 36 
GHz.  

Similarly, the  ITU-R P.526-13  radius of curvature is extremely higher than the 
occultation distance based radius of curvature. At frequency of 1 GHz , the percentage 
difference in radius of curvature (%) is about 218% and the difference increases with 
frequency to as high as 395% at 36 GHz. In all the frequencies considered, the 
occultation distance remained constant at 1435.7 m. 

Table 2: The diffraction loss, radius of curvature and radius of Fresnel zone for different 
frequencies and radius of curvature methods 

f (GHz) 
R (m) By 

ITU 
Method 

R(m) By 
Occultation 

Method 

Percentage 
Difference in 

R (%) 

Diffraction 
Loss (dB) 
Based on  

ITU R 

Diffraction 
Loss (dB) 
Based on  

ITU 
Occultation 
Distance R 

Percentage 
Difference 

in 
Diffraction 
Loss (%) 

Radius of 
First 

Fresnel 
Zone (m) 

Occultation 
Distance 

(m) 

1 208913.4 65607.6 218.4 47.5 34.1 39.5 29.2 1435.7 

3 244334.8 65607.6 272.4 64.6 43.9 47.4 16.9 1435.7 

6 275391.7 65607.6 319.8 83.9 52.5 59.8 11.9 1435.7 

12 317868.0 65607.6 384.5 111.1 64.0 73.5 8.4 1435.7 

24 317868.0 65607.6 384.5 140.8 81.2 73.4 6.0 1435.7 

36 324776.4 65607.6 395.0 163.2 93.6 74.5 4.9 1435.7 

4. Conclusions 
The effect of radius of curvature  on the rounded edge diffraction loss computed by the  
ITU-R P.526-13  rounded edge diffraction loss method is presented. The radius of 
curvature is computed using two methods , namely, the  ITU-R P.526-13  method and 
the occultation distance-based  method. The path profile considered in the study is a 
double edged hilltop obstruction.The results show that the rounded edge diffraction loss 
computed by the ITU 526 -13 method is significantly affected by the radius of curvature. 
Also, for high occultation distance obstructions, the difference in the radius of curvature 
of the rounded edge and hence on the diffraction loss obtained  can be very high. The 
result therefore shows that the ITU 526 radius of curvature method  should be 
reviewed to ascertain the specific conditions it can be employed. 

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Copyright © 2017 Mfonobong Charles Uko, Uduak Etim Udoka, Chibuzo Promise 
Nkwocha. This is an open access article distributed under the Creative Commons 
Attribution License, which permits unrestricted use, distribution, and reproduction in 
any medium, provided the original work is properly cited.