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Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3496-3501 3496  
  

www.etasr.com Shastri et al.: Nonuniform C-Band Loop Antenna 

 

Nonuniform C-Band Loop Antenna  
A New Approach for Future UWB Applications 

 

S. P. Shastri 

Faculty of Engineering 

Pacific University,  

Rajasthan, India 

shailendra.shastri@thakureducation.org 

R. R. Singh 

Thakur Educational Trust, 

Mumbai, India 

ravishrsingh@yahoo.com 

K. V. Ajetrao 

Electronics and Telecommunication 

Department, K. J. Somaiya College of 

Engineering, Mumbai, India 

kiranjetrao@somaiya.edu 

 

 

Abstract—Antenna design becomes very difficult at very small 
wavelengths and a special lab is required to manufacture a small 
antenna which costs a lot. A new approach is proposed to 
enhance the bandwidth of the loop antenna which can be 
designed at very high frequency using conventional PCB design 
technique. The proposed antenna is a nonuniform loop and 
covers UWB frequency range. The nonuniform structure of the 
loop is designed using the concept of both thin and thick loop 
antenna together which leads to an improvement in the antenna 
bandwidth. The proposed nonuniform loop antenna covers a 
band of 91.4% which is higher than any existing printed loop 
antenna. The frequency ranges from 3.54GHz to 9.5GHz and the 
measured result is in agreement with the simulated result. This 
technique can be very helpful in designing UWB antennas in the 
range of Ku band or higher than this. 

Keywords-coplanar stripline; thin loop antenna; thick loop 

antenna; wire antenna; ultra wide band; nonuniform loop antenna 

I. INTRODUCTION  

UWB is a need of present and future communication 
systems as demand for more data is increasing. High-speed 
data transfer requires the availability of a larger band. In order 
to fulfill the need of larger bandwidth, broadband antennas are 
used as transmitting and/or receiving elements. Other UWB 
applications include location tracking and ground penetrating 
radars. So far monopole antennas appeared as strong candidates 
to fulfill the requirements of UWB applications. In order to 
improve gain and other electrical and radiation characteristics, 
metamaterials or EBG structures were added to monopole 
antennas. Dipole printed antennas fed with coplanar stripline 
(CPS) cover bandwidth from 3.1GHz to 11.4GHz. This 
structure has too many dimensional parameters in the antenna 
design [1]. A closed loop structure provides larger scope for the 
researchers to contribute. A square printed loop with L shape 
portion to its arm offers excellent performance at the lower-
band of UWB system, ranging from 3.1GHz to 5.1GHz [2]. 
The antenna exhibits a -10dB return loss bandwidth over the 
entire frequency band. It is found that the lower band depends 
on the L portion of the loop antenna however the upper 
frequency limit is decided by the taper transmission line. The 
percentage of the bandwidth of the antenna is 48.78%. A 
printed loop antenna fed with coplanar waveguide can produce 
bandwidth of 1GHz and 1.14GHz. This antenna is suitable for 

applications in PCS and IMT 2000 systems. The antenna has 
high gain with omnidirectional radiation pattern [3]. A small 
size loop antenna fed with CPW line produces a 70% 
bandwidth. The small size of the antenna makes it useful for 
array applications [4]. A single loop antenna has a narrow 
circular polarized bandwidth. When this antenna is added with 
another loop antenna as a passive element, then a second band 
is created and the combination of the antennas produces a 
larger bandwidth with circular polarization [5]. The band 
enhancement technique [2] was extended to a circular loop and 
bandwidth of 88.6% was achieved. The proposed work failed 
to give any justification on the enhancement of bandwidth and 
the impact of proposed shape on the antenna radiation pattern 
was not considered.  

II. PROPOSED NONUNIFORM LOOP ANTENNA 

A circular loop antenna with a thickness factor larger than 9, is 

called a thin loop antenna, otherwise it is called a thick loop 

antenna. The thin loop has multiple resonating frequencies and 

larger resistance with fluctuating characteristic. On the 

contrary, a thick loop antenna is capacitive in nature with low 

and uniform resistance [6]. The thickness factor is defined in 

(1), where Ω is the thickness factor, � is the radius of the loop 
in m and � is the wire radius in m: 

Ω = 2	ln	(2
� �� )    (1)  

A loop antenna is basically a narrow band antenna. The 
bandwidth of the antenna can be improved when both thin and 
thick loop antennas are added together to have a uniform 
standing wave ratio (SWR) [7]. Its loop is comprised of a thick 
loop with 8.8 thickness factor and a thin loop with 11.7 
thickness factor and covers 88.6% bandwidth. A wire loop 
antenna can be modified into a printed loop antenna using (2) 
as given in [8]. The thickness factor can be calculated using (1) 
and (2), where w is the width of the printed loop and b is the 
wire radius: 

� =	
 4⁄      (2) 

In order to further improve the loop antenna bandwidth, a 
new geometry is proposed and is shown in Figure 1. The 
proposed geometry has a gradual increase in the width of the 
loop to have thin and thick loop properties together, unlike the 



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3496-3501 3497  
  

www.etasr.com Shastri et al.: Nonuniform C-Band Loop Antenna 

 

geometry in [7], which also has a step change in the width of 
the loop.  

 

 
(a)      (b) 

Fig. 1.  Nonuniform loop with (a) feed at narrow width W1 (b) feed at 
wide width W2. 

A loop antenna falls under two categories: 1) A large loop 
whose circumference is equal to or larger than a wavelength at 
a chosen frequency, 2) a small loop with circumference smaller 
than λ/10. A large loop is a good radiator while a small loop is 
a good receiver [9]. In order to cover the least frequency of 
2GHz, the approximate radius of the loop using (3) and (4) is 
24mm and the width of the loop is 1mm. Ω of the loop is 12.76 
so it is thin in nature. The same antenna for 12mm width has Ω 
of 7.26 and is, a thick loop. 

� � 2
� � �     (3) 

� � � �⁄      (4) 

where � is the circumference of the loop, r is the radius of the 
loop in m, � is the wavelength in m, � is the frequency in Hz 
and �is the speed of light in m/s in free space. The antenna is 
simulated using CST STUDIO. The substrate used is FR-4 with 
a height of 0.8mm. 

III. FEED LOCATION AND WIDTH IMPACT ON THE 

PERFORMANCE OF THE PROPOSED ANTENNA 

The proposed geometry has minimum width W1 and 
maximum width W2 to give a nonuniform dimension. The 
outer radius of the loop is taken as 24mm. In order to analyze 
the characteristics of the nonuniform loop and the effect of this 
geometry on feed location, a feed is applied at one width and 
the same or other width of the loop varies.  

A. Feed Impact at Narrow Width W1 with Varying Width W2 

The possible advantage of the proposed structure is that 
there can be infinite locations for antenna excitation. This is 
because at different locations the feed will experience different 
loop width. Therefore the loop electrical properties will be 
different for different locations of the excitation due to its 
nonuniform structure. Nonuniform loop with thin width W1 of 
1mm and thick width W2 of different values ranging from 
6mm to 12mm is simulated. The feed to the loop is placed at 
the thin end W1. The result of the proposed nonuniform loop is 
compared with 1) a thin loop of 23.5mm radius with 1mm 
width having Ω=12.76 and 2) a thick loop of 18mm radius with 
12mm width having a thickness factor of 7.26. In order to have 
the same loop size, i.e. thin loop, thick loop and nonuniform 
loop, the outer radius is kept 24mm. Since the proposed 
nonuniform loop has W1=1mm and width W2 varying from 
6mm to 12mm, it is a combination of thin and thick loop. A 
thin loop of thickness factor of 12.76 shows a huge variation in 
resistance value. It ranges from 80Ω to more than 400Ω as is 

observed in Figure 2(a). The thin loop resonates at about 
1.9GHz as shown in Figure 2(b). The thick loop of 7.26 
thickness factor, as observed in Figure 2(b), has stable 
resistance and resonates at 6GHz.  

 

(a) 

 
 

(b) 

 

Fig. 2.  Comparison of impedances of uniform and nonuniform loop when 

feed is applied at narrow width W1 and varying width W2. 

It can be observed in Figure 2(a) that the resistance 
variation of the proposed loop antenna is reduced to a greater 
extent but it is larger than the resistance of the thick loop for all 
simulated cases. Similarly, the reactance of the nonuniform 
loop shows less variation when compared to the reactance of 
the thin antenna but it is larger than the reactance of the thick 
loop antenna as shown in Figure 2(b). 

B. Feed Impact at Wide width W2 with Varying Width W2 

In order to analyze the effect of feed locations on the 
characteristic of the nonuniform loop antenna, the feed is 
placed at wide end W2 as shown in Figure 1(b). The width W2 
varies from 6mm to 12mm, while W1 is kept constant to 1mm. 
The behavior of the impedance of the nonuniform loop is 
shown in Figures 3(a) and 3(b). It is observed that the 
resistance of the nonuniform loop approaches the resistance of 
the thick loop antenna of uniform width of 12mm with Ω=7.26. 
The resistance varies between 24Ω to 75Ω from 3GHz 
onwards. In Figure 3(b), it can be observed that as W2 
increases from 6mm to 12mm, the reactance of the nonuniform 
loop decreases and approaches the reactance of the thick loop 
(Ω=7.26) of 12mm width. The reactance of the nonuniform 
loop ranges from -75Ω to +50Ω for frequencies from 3.4GHz 
and onwards. The impedance of the proposed nonuniform loop 
under this case is smaller than in the previous case. The overall 



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3496-3501 3498  
  

www.etasr.com Shastri et al.: Nonuniform C-Band Loop Antenna 

 

impedance of the proposed loop for all cases is much smaller 
than the impedance of the thin loop with thickness factor of 
12.76. Any increase in W2 of the nonuniform loop reduces 
thickness factor of the antenna and antenna impedance 
approaches the impedance of thick loop with thickness factor 
7.26. 

 

(a) 

 
 

(b) 

 

Fig. 3.  Comparison of the reactance of uniform and nonuniform loop 

when feed is applied at wide width W2. 

C. Feed Impact at Narrow Width W1 with Varying Width W1 

Now the feed is placed at W1 and width W2 is kept at 
6mm. W1 varies from 1mm to 2mm. The result of this 
nonuniform loop is compared with the uniform loop of 24mm 
outer radius with 6mm width. The outer radius of the 
nonuniform loop is kept at 24mm in order to keep the same 
maximum dimension of uniform and nonuniform loop. The 
uniform antenna of 6mm width with an outer radius of 24mm 
has uniform resistance less than 50Ω from 3.3GHz and 
onwards as shown in Figure 4(a). The nonuniform loop with 
W2 of 6mm and varying width W1 from 1mm to 2mm shows 
that antenna resistance decreases with increase in W1. Any 
increase in W1 leads to uniformity in the structure of the loop 
and also causes a drop in the thickness factor of the proposed 
antenna. Therefore the resistance of the nonuniform loop 
antenna decreases as shown in Figure 4(a). The antenna with 
uniform width of 6mm resonates at 11GHz. It is capacitive 
from 1GHz to 11GHz and then switches to inductive reactance. 
On the other hand, the reactance of the nonuniform loop is 
larger and capacitive from 1GHz to 12GHz and above. As W1 
increases from 1mm to 2mm, the antenna reactance reduces for 
obvious reasons as shown in Figure 4(b). 

(a) 

 
 

(b) 

 

Fig. 4.  (a) Resistance and (b) Reactance comparison of uniform and 

nonuniform loop when feed is applied at varying narrow width W1. 

D. Feed Impact at Wide Width W2 with Varying Width W1 

Now the feed is located at wide width W2 and the width 
W1 varies from 1mm to 2mm. W2 is kept constant to 6mm. 
When the feed is shifted to W2 end, there is a huge difference 
observed in the reactance of the nonuniform loop antenna. In 
the uniform antenna, the shift in feed location does not 
influence the characteristics of the antenna as the dimension 
seen by the two terminal sources triggering the antenna is 
uniform. This is not the case with the nonuniform loop for the 
same two terminal sources. The nonuniform loop with thin 
dimension W1 of 1mm shows larger resistance. There is a 
continuous decrease in the resistance with increase in W1 as 
this leads to uniformity of the proposed structure. The variation 
in resistance is shown in Figure 5(a). Larger resistance is 
observed from 2GHz to 2.6GHz for W1 variation from 1mm to 
1.5mm. The variation in resistance for W1 of 2mm is very 
small and is well aligned with the resistance variation of the 
uniform loop of width 6mm from 2.7GHz onwards. It can be 
observed in Figure 5(b) that the reactances of uniform and 
nonuniform loop are well aligned from 3GHz and above. The 
two antennas, uniform and nonuniform, differ in their reactance 
from 2.45GHz to 3GHz. Table I summarizes the impedance 
behavior of the loop with different W2 of 8mm and 10mm 
along with the earlier case of width W2 of 6mm. Width W1 
ranges from 1mm to 2mm for all three cases. It can be 
concluded that for a feed at W1 antenna impedance decreases 
significantly as W2 increases. A huge fall in antenna 
impedance is observed when the loop is fed at W2. Therefore 
antenna impedance is a strong function of the feed location. 
Furthermore, the antenna impedance can be varied by changing 
W1 and W2. This property of the proposed loop is not 
available in any other loop antenna available in the literature.  



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3496-3501 3499  
  

www.etasr.com Shastri et al.: Nonuniform C-Band Loop Antenna 

 

(a) 

 
 

(b) 

 

Fig. 5.  (a) Resistance and (b) reactance comparison of uniform and 

nonuniform loop when feed is applied at wide width W2. 

TABLE I.  BEHAVIOUR OF PROPOSED NONUNIFORM LOOP ANTENNA 

W2 
(mm) 

W1 
(mm) 

R/X (Ω) 
(4GHZ to 5GHz) 

R/X (Ω) 
(8GHZ to 9GHz) 

R/X (Ω) 
(11GHZ to 12GHz) 

Feed at 
W1 

Feed at 
W2 

Feed at 
W1 

Feed at 
W2 

Feed at 
W1 

Feed at 
W2 

6 

1 219/-134 49/-77 102/-87 23/-18 87/-77 21.3/4 

1.5 170/-124 52/-75 77/-80 24/-19 64/-66 21.6/3 

2 140/-113 52/-72 62/-69 23/-19 52/-54 21.7/3.4 

8 

1 183/-148 41/-51 97/-93 19/-105 87/-79 19/25 

1.5 146/-134 41/-49 76/-82 19/-1.7 66/-65 18/25 

2 122/-122 40.5/-47 63/-72 19/-1.5 53/-52 18/25 

10 

1 178/-144 31/-34 102/-100 17/13 88/-76 19/48 

1.5 140/-132 31/-33 80/-88 17/13 63/-64 19/47 

2 117/-120 30/-32 65/-74 16/13.8 51/-52 19/46 

R-Resistance, X-Reactance 

IV. LOCATING FEED FOR OPTIMUM BANDWIDTH 

From the analysis above, it is concluded that antenna 
impedance is a function of the feed location. This section is 
dedicated to finding a suitable location of the feed to have the 
maximum bandwidth. The feed is applied from W1 end at 0

0
 

and is shifted to W2 end at 180
0
 as shown in Figure 6(a). The 

reflection coefficient for all cases is compared in order to find 
the optimum feed location. Since the loop is a balanced 
antenna, it cannot be excited directly with SMA connector or 
coaxial cable. In order to excite the proposed loop with the help 
of SMA connector or any other unbalanced line, a coplanar 
strip line (CPS) is added to the loop as shown in Figure 6(b). 
For the simulations the outer radius of the nonuniform loop is 
kept at 24mm, the inner radius is 17.75mm with W1 of 2mm 
and W2 of 12mm. The inclusion of the CPS line converts the 
unbalanced field distribution from the SMA feed connector to a 
balanced field distribution at the loop [10]. The CPS feed line 

is placed at different locations and the results are compared in 
Figure 7. The detailed dimension of the CPS line is included in 
Figure 6(b). 

 

(a) 

 
 

(b) 

 

Fig. 6.  The proposed nonuniform (a) showing various feed locations from 

W1 to W2 (b) loop with CPS feed line. 

 

 
Fig. 7.  Comparison of the reflection coefficient of the  nonuniform loop 

for different feed locations. 

It can be observed that the shift in the location of the feed 
influences the bandwidth of the antenna since the antenna 
impedance changes due to the change in the location of the 
feed as observed above. Table II summarizes the performance 
of the proposed loop in terms of % bandwidth of the loop with 
respect to different feed locations. It can be observed that the 
antenna gives the highest bandwidth when the feed is applied at 
135

0
. The available bandwidth is 91.4%. The band has lower 

cut off frequency of 3.54GHz and higher cut-off frequency of 
9.5GHz. Table III compares the proposed nonuniform loop 
antenna with other existing loop antennas. It can be observed 
that the proposed loop has the highest electrical and radiation 
bandwidth. Figure 8 shows the radiation patterns in the range 
of 3.54GHz to 9.5GHz. The loop antenna is placed in X-Y 
plane as shown in Figure 6(b). The radiation pattern is of end 
fire type and is available along -Y axis, opposite to the feed of 
the loop antenna. It was observed that the pattern is always 
available opposite to the feed of the loop for all cases listed in 
Table II. It is important to note here that when the proposed 
loop is compared with the loop proposed in [7], there is very 
little improvement in the antenna bandwidth. The advantages 
of the proposed loop over the earlier are summarized in Table 
IV. The earlier loop requires BALUN transformer but the loop 
presented in this paper does not require it, so it occupies a 
smaller area on PCB. In addition, the size of the presented loop 



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3496-3501 3500  
  

www.etasr.com Shastri et al.: Nonuniform C-Band Loop Antenna 

 

is almost half the size of the earlier loop whose outer 
dimension was 45mm. There are only three distinct locations 
for feed in the earlier loop: a) on the wide arm of the loop, b) 
on the thin arm of the loop, and c) between the interface of 
wide and thin arm of the loop. The loop in this paper has 
theoretically infinite locations to feed the antenna. 

TABLE II.  LOOP PERFORMANCE COMPARISON FOR DIFFERENT FEED 
LOCATIONS USING CPS. 

Sr. No. Feed Locations f1-f2 % Bandwidth 
1 0

0
 4.9-6.7 31 

2 22.5
0
 5.4-7.6 34 

3 45
0
 6.5-9.2 34 

4 67.5
0
 4.8-8 50 

5 90
0
 3.58-6.7 60.7 

6 112.5
0
 3.7- 8.8 81.6 

7 135
0
 3.54-9.5 91.4 

f1, f2- lower and upper cut off frequency 

TABLE III.  PROPOSED AND OTHER LOOP ANTENNAS COMPARISON 

Sr. No. %Bandwidth Reference Year 
1 88.6 [7] 2016 

2 67 [11] 2015 

3 40.7 [12] 2012 

4 70 [4] 2010 

5 48.8 [2] 2005 

6 91.4 Proposed ------- 

TABLE IV.  PROPOSED LOOP AND EARLIER LOOP COMPARISON 

 
Property 

Size % Bandwidth 
Feed 

Locations 
Radiation 
Pattern 

Proposed 
Loop 

Smaller 91.4 Infinite Stationary 

Earlier 
Loop 

Larger 88.6 Three Not available 

V. MEASUREMENTS AND DISCUSSION 

Figure 9 shows a photograph of the proposed antenna. The 
proposed nonuniform loop is excited with a SMA connector 
directly. Figure 10 shows the measured and simulated 
reflection coefficient for the loop with CPS line feed at 135

0
. 

The measured result is in good agreement with the simulated 
one and ensures 91.4% bandwidth. The outer dimension of the 
loop is 24mm i.e. the antenna diameter is 48mm. The 
significant observation is that the loop antenna with outer 
dimension of 24mm and thickness factor of 12.76 resonates at 
around 1.9GHz. It resonates at about 6GHz when thickness 
factor changes to 7.26 as discussed earlier. The proposed loop 
is a combination of thin and thick loop with resonant frequency 
falling between 1.9GHz and 6GHz. The lowest cutoff 
frequency of the proposed loop is nearly 3.54GHz for which 
the antenna dimension should be smaller than 48mm. Therefore 
this technique can be useful for designing very high frequency 
antennas such as Ka band and higher where the dimension of 
the antenna becomes too small and a special lab is required for 
the manufacturing of the antenna. 

VI. CONCLUSIONS 

The proposed nonuniform loop antenna has the unique 
property of having infinite possibilities to feed the antenna. The 

antenna offers different electrical properties for different feed 
locations. This property is not available in the conventional 
structure of loop antenna.  

 

(a) 

 
 

(b) 

 
 

(c) 

 
 

(d) 

 
 

(e) 

 
 

Fig. 8.  Radiation pattern of the nonuniform loop at different frequencies. 



Engineering, Technology & Applied Science Research Vol. 8, No. 5, 2018, 3496-3501 3501  
  

www.etasr.com Shastri et al.: Nonuniform C-Band Loop Antenna 

 

The proposed structure with the CPS feed line can be 
excited with a coaxial SMA connector. The combination of 
thin and thick loop offers a wide bandwidth of 91.4%. The 
proposed dimension of the loop is expected to cover the lowest 
frequency of 2GHz but the lowest frequency obtained is 
3.54GHz. This leads to an increase in the antenna dimension. 

 

 

Fig. 9.  Photograph of the proposed nonuniform loop antenna. 

 

 

Fig. 10.  The measured and the simulated reflection coefficient of the 

nonuniform loop antenna. 

This approach can be used to design an antenna for Ka band 
applications or higher than Ka band where the antenna size 
becomes so small that a special lab is required to manufacture 
it. If this technique is used to design antennas at such a high 
frequency, the dimension of the loop will be sufficiently larger 
and simple pcb design technique can be used to manufacture 
the antenna at low cost. The proposed antenna shows wider % 
bandwidth than any other printed wideband loop antenna. The 
simulated and measured bandwidth of the loop is 91.4% with 
unidirectional radiation pattern oriented opposite to the feed. 
Since the pattern is available in the opposite side of the feed, 
the proposed antenna can have multiple feed points and pattern 
reconfigurability can be achieved.  

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