Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
Vol. 1, No. 2, November 2017, pp. 61-68  61 

                                                                                                                    DOI: 10.17977/um016v1i22017p061 

Development of a Ferrite-Based Electromagnetic Wave 
Detector 

Muhammad Hanis Bin Zakariah1,*, Poppy Puspitasari2, Nur Azliza Ahmad3 

1Department of Electrical and Electronic Engineering, Universiti Teknologi PETRONAS, Bandar Seri Iskandar, 31750 
Tronoh, Perak Darul Ridzuan, Malaysia 

2Department of Mechanical Engineering, Engineering Faculty, Universitas Negeri Malang, Semarang St. No 5, Malang, 
East Java, Indonesia, 65140 

3Faculty Engineering, Mahsa University, Saujana Putra Campus, 46210 Jenjarom, Selangor  
*mhanisz@gmail.com 

 

 
ABSTRACT  

Direct detection of hydrocarbon by an active source using electromagnetic (EM) wave termed Sea Bed 
Logging (SBL) has shown very promising results. However, currently available electromagnetic wave 
technology has a number of challenges including sensitivity and lapsed time. Our initial response to this 
issue is to develop a ferrite-based EM wave detector for Sea Bed Logging (SBL). Ferrite bar and copper 
rings in various diameters were used as detector 1 (D1). For Detector 2 (D2), toroid added with copper 
wires in different lengths at the centre of it were used. The first experiment is to determine the inductance 
and resistance for both detectors by using LCR meter. We obtained the highest inductance value of 0.02530 
mH at the ferrite bar when it was paired with a 15 cm diameter copper ring and 0.00526 mH for D2 using a 
100 cm copper wire placed at the centre of the toroid. The highest resistivity for D1 was measured at ferrite 
bar paired with a 15 cm diameter  copper ring and 1.099 Ω when using 20 cm length of copper wire. The 
second interest deals with voltage peak-to-peak (Vp-p) value for both detectors by using oscilloscope. The 
highest voltage value at the ferrite bar of D1 was 25.30 mV. While at D2, the highest voltage measured was 
27.70 mV when using a 100 cm copper wire. The third premise is the comparison of sensitivity and lapsed 
time for both detectors. It was found that D1 was 61% more sensitive than D2 but had higher lapsed time 
than D2..  
 
Copyright © 2017Journal of Mechanical Engineering Science and Technology 
All rights reserved 
Keywords: Sea Bed Logging, Detector, Sensitivity,Lapsed time 

I. Introduction  
In SBL, a mobile horizontal electric dipole (HED) source and an array of seafloor electric field 

receivers are utilised. The transmitting dipole emits a low frequency electromagnetic signal that 
propagates into the seabed [1]. The array of sea floor receivers measures both the amplitude and the 
phase of the received signal directly from the transmitter, and waves reflected and guided from the 
seabed. The received signal depends on the resistivity structure beneath the seabed [2]. 
Characterisation and detection of the reservoir using SBL are based on the electrical conductivity 
consisting in all geological media. The principle of conductivity differencein geological media is 
applied in this technology [3]. Besides its advantage in segregating a resistivity in a non-conductive 
layer and conductive formation beneath the sea floor, the electromagnetic method has a robustness 
characteristic against bad operating conditions such as high temperature and high pressure [4]. 

Many types of electromagnetic detectors have been developed for use in this type of hydrocarbon 
detection method.  However, currently available detectors have a number of challenges and one of 
them is the reading instability that can result in a misinterpretation. This could lead to the loss of 
significant investments.  

This paper describes the initial work to develop an EM detector with high sensitivity and short 
recovery time for SBL.  The first part of this work is to compare the sensitivity for both detectors. 
Sensitivity of detectors is an important aspect for SBL method. In the previous work, 
electromagnetic detector was used to geophysically detect  layer boundaries  [5]. This workhas been 
done because difficulties exist in magneto telluric and geomagnetic depth sounding method; these 
methods are geophysical methods sensitive to mantle melt. The selection of detectors plays a major 
role to gain good detection results. Since sensitivity was taken into account, another aspect that 
needs to be considered is lapsed time or recovery time.  

mailto:*mhanisz@gmail.com


62 Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
 Vol. 1, No. 2, November 2017, pp. 61-68 

 Muhammad Hanis Bin Zakariah1et.al (Development of a Ferrite-Based Electromagnetic) 

The second premise dealt in this work is the determination of recovery time. In detail, EM 
detector for SBL needs a higher sensitivity with a shorter lapsed time that can prevent any error in 
SBL’s further data processing. EM detection system used to detect buried metallic in the soil [6] 
found errors in the data caused by uncertainties in sensor height. As a result,  a fluctuation in data 
occurred. ] These two parameters are important for sensitive EM detectors because with the 
decreasing of recovery times, the efficiency of the detector will  increase. Output of the EM wave 
detected was not  affected by a pile-up caused by incoming EM wave. Now we can look thoroughly 
to the magnetic hysteresis element of the magnetic material used in this work. Hysteresis is a 
phenomenon in which  the magnetic field lags behind the electric field [7]. Details about the 
hysteresis will be reviewed more comprehensively in the Results and Discussion section. 

II. Materials and methods 
A 20-turn toroidal transmitter with an aluminium rod placed in the centre of the toroid was used 

in this work. It was supplied by 5 MHz frequency of square wave from a wave generator (Textronic 
AX493). The distance between the transmitter and the detector was fixed at one meter, as described 
in Figure 1 and Figure 2. The properties of the transmitter are summarised in Table 1. Two types of 
EM detectors were investigated. The responses from the detectors were then determined by 
measuring the induced voltage with an oscilloscope. 
 

 

Fig. 1. Block diagram of   transmitter-detector system 

 
Fig. 2. Block diagram of  transmitter-detector system 

Table 1.  Transmitter properties 

 Transmitter parameters  Propertieses 
aterial Toroid with 20 turns and aluminium rod in the centre of the toroid 

Frequency 5MHz 
Distance from detector 1 meter 

Waveform Square-shaped 
 



ISSN: 2580-0817 Journal of Mechanical Engineering Science and Technology 63 
 Vol. 1, No. 2, November 2017, pp. 61-68 

 Muhammad Hanis Bin Zakariah1et.al (Development of a Ferrite-Based Electromagnetic) 

Fig. 3. Detector 1 (D1) set up consisting of a of a ferrite bar 
and copper wire 

 
Fig. 4. Schematic diagram of D1 

Fig. 5. Detector (D2) set up consisting toroid 
and copper wire 

 
Fig. 6. Schematic diagram of D2 

  

Table 2.  Properties of ferrite material manufactured by ACME Ferrite Products Sdn Bhd (Source: 
www.acme.com.my) 

Term Symbol Conditions Value Unit  
Initial Permeability µ i 10kHz 

25oC 
800 ± 25%  

Max. Magnetic Flux 
density 

Bm 50Oe 
25oC 

3100 Gauss 

Residual Magnetic 
Flux density 

Br 25oC 1/00 Gauss 25oC 

Coercive Force Hc  0.65  
Relative Loss factor tan ɗ/ µi 25oC  0.15 MHz 10-3 
Electrical Resistivity p DC  

25oC  
≥108 Ωcm 

Temperature 
Coefficient 

 20oC.80oC  ≤5 10-6K-1 

Curie Temperature Tc  >150 oC 
Density ρ  5000 Kg/m3 

 
Two types of EM wave detectors were selected in the present work. Figure 2 and Figure 3 show 

the arrangements of the two types of detectors used..In addition, their schematic drawings  are 
presented in  Figure 4 and Figure 5.     

 

http://www.acme.com.my)


64 Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
 Vol. 1, No. 2, November 2017, pp. 61-68 

 Muhammad Hanis Bin Zakariah1et.al (Development of a Ferrite-Based Electromagnetic) 

Table 3.  Properties of detector (D1 and D2). 

 Detector 1 (D1) Detector 2 (D2) 

Copper wire Shape Ring-shaped with variable diameter Wire 
Thickness 0.8mm with variable diameter 0.8mm with variable length 
Location Placed vertically around the ferrite bar Placed at the centre of toroid 

Toroid None ID 1.5mm 

OD 2.5mm 

Type Type D28 with constant electric 
source applied  

Ferrite Bar Type D28 with 20 wind by copper wire (thickness 
0.8mm) 

None 

 
Table 3.  describes the properties  of both detectors. The diameter of copper ring in D1 varies 

from 7.5mm, 8.0mm, 9.0mm, 11.0mm, 13.0mm, 15.0mm, to 20.0mm.  
Measurements of parameters for both detectors have been performed by using oscilloscope and 

LCR meter (Instex LCR-16). Parameters that we have put into consideration for both detectors were 
voltage peak to peak (Vp-p), inductance (L), resistance, (R) and recovery time (t). Moreover, 
measurements of Vp-p have been carried out by using two oscilloscopes at the ferrite bar and copper 
ring; single function and both function operations were performed. Table 3 shows the clear method 
of operating oscilloscope  during the measurement of Vp-p for D1. 

Measurements of inductance (L) and resistivity (R) during detection period have been performed 
by using LCR meter at each ferrite bar and copper ring. 

Detector 2 consisted of a small toroid as a magnetic feeder with a copper wire in the centre of it. 
A constant magnetisation was supplied by connecting 9V dry-cell battery to the toroid. Copper wires 
(0.8mm thickness) with different set of length varying from 10cm, 20cm, 30cm, 40cm, 50cm, 60cm, 
70cm, 80cm, 90cm to 100 cm were placed in turn at the centre of magnetic feeder. The measurement 
of V p-p for detector 2 have been taken by using oscilloscope at both ends of copper wire which had 
been placed at the centre of toroid during receiving an electromagnetic wave from the transmitter. 
By using the LCR meter, the inductance and resistance value have been determined during the 
detection period of EM wave. 

Lapsed time measurement was performed to determine hysteresis effect  by the following 
methods. When the detectors were exposed to EM wave, the signal detected at the oscilloscope 
showed a proportional response (due to the properties of the detector). Time taken by a signal 
detected at oscilloscope at the peak value (when the EM source transmitter was on) was dropped off 
to the base line when EM wave source (transmitter) is off were measured.  

III. Results and discussion. 
Measurements of sensitivity and lapsed time for the two detectors (D1 and D2) were carried out  

using a ferrite-core material [11]. Table 4 shows the results of Vp-p gained from D1 with the 
changing of diameter of the copper ring. The experiment conducted with oscilloscopes was divided 
into two sections, i.e.  single function operation and both functions operation. During the single 
function operation of oscilloscope at the ferrite bar, the highest Vp-p value recorded was 45.60mV, 
which was using a 15.0-cm-diameter copper ring. However, it was drastically decreased when both 
functions operation of oscilloscopes was operated. 

Table 4.  Vp-p measurement method for D1using oscilloscope. 

 Oscilloscope function 
Single operation Both operation 

Ferrite Bar Operated  Operated  
Copper ring Non-operated Operated  
Ferrite Bar Non-operated Operated  
Copper ring Operated  Operated  



ISSN: 2580-0817 Journal of Mechanical Engineering Science and Technology 65 
 Vol. 1, No. 2, November 2017, pp. 61-68 

 Muhammad Hanis Bin Zakariah1et.al (Development of a Ferrite-Based Electromagnetic) 

Table 5.  Vp-p values for D1 

Diameter of copper ring 
(cm) 

Vp-p (mV) single function 
operation 

Vp-p (mV) both function 
operation 

  Ferrite Ring Ferrite Ring 
20.0 31.80 19.40 23.40 5.04 
15.0 45.60 17.10 7.79 7.79 
12.0 37.60 19.60 36.00 6.41 
11.0 24.40 19.60 25.30 14.50 
9.0 36.20 11.60 34.00 11.20 
8.0 37.80 9.43 10.70 10.70 
7.5 31.20 11.30 31.20 11.30 

 

Fig. 7. Graph pattern for Vp-p values for ferrite bar 
and copper ring from D1 during single operation 

of oscilloscope 

Fig. 8. Graph pattern for Vp-p values for ferrite bar 
and copper ring from D1 during both operations 

oscilloscope. 

Table 6.  L, R and Vp-p values for D1 

Diameter of copper ring (cm) 
  

L (mH) x 10
 -2 R (Ω) Vp-p (mV) 

Ferrite Ring Ferrite Ring Ferrite Ring 
20.0 2.36 2.08 1.90 5.00 23.40 5.04 

15.0 2.53 1.86 8.97 7.24 7.79 7.79 

12.0 2.33 1.80 2.61 2.69 36.00 6.41 

11.0 2.35 1.66 3.02 3.20 25.30 14.50 

9.0 0.19 23.50 1.37 1.80 34.00 11.20 

8.0 2.35 1.63 1.91 2.55 10.70 10.70 

7.5 2.34 1.75 1.21 2.35 31.20 11.30 

 
In another work done on EM wave logging system for determining resistivity and dielectric 

constant of earth formations [8], it was proved that the resulting magnetic fields produced by 
electromagnetic induction from a high frequency alternating current in the earth formations 
surrounding the well bore were detected at the spaced receiver coil by sensing the induced currents 
or voltages in the receiver coil caused by the secondary currents flowing in the formations. Another 
former research found that when the copper ring and ferrite bar were exposed to an EM wave, their 
existing electric fields were found to be  proportional with EM field [7]. The electric fields from 
ferrite bar and copper ring are supposed to enhance each other and lead to a higher value of Vp-p 
during both function operations than during single function operation of oscilloscope. However, 
when both function of oscilloscope test was conducted, there was a significant decrease in Vp-p at 
ferrite bar and copper ring to 7.76 mV both. This result (Figure 3 and 4) showed that during 
detection period, the magnetic field from copper ring and ferrite bar could not enhance each other. 
Besides, the testing result of wider diameter of copper ring was expected to meet a threshold limit at 



66 Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
 Vol. 1, No. 2, November 2017, pp. 61-68 

 Muhammad Hanis Bin Zakariah1et.al (Development of a Ferrite-Based Electromagnetic) 

a certain diameter of copper ring. The achieved threshold limit led to a conclusion that magnetic 
field at the ferrite bar is not affected by magnetic field of the copper ring. 

Generally, the results  of inductance (L), resistivity (R), and Vp-p values for D1  are presentedin 
Table 4. The table shows the results obtained from measurements by using oscilloscope and LCR 
meter. Figure 7 and Figure 8 show the results of inductance and resistivity values obtained from D1.  

As shown in Figure 7 and Figure 8, the average value of the inductance (L) and resistance (R) at 
the ferrite was higher than the one  of L and R at copper rings.  

In measurement of electromagnetic and electric field for D2, Figure 5 shows that resistivity was 
increased when the length of copper wire was increased as well. From the resistivity value, we 
concluded that an electric field existed. One important difference between electromagnetic poles and 
electric charges is that electric charges can be isolated, but magnetic poles always exist in pairs [9]. 
This was proven by inductance values  indicatingthe strength of the magnetic field in D2. 

Figure 12 shows the inductance values gained from LCR meter when electromagnetic field was 
applied. Inductance can be described as a measurement of how much magnetic energy stored in the 
detector [10]. The use of 100cm copper wire in the centre of toroid generated the highest value of 
inductance (0.00526 µH), resistivity (0.9001 Ω), and Vp-p (27.70mV) 

 

Fig. 9. Graph pattern for inductance values for ferrite 
bar and copper ring from D1 

Fig. 10. Graph pattern for resistance values for 
ferrite bar and copper ring from D1 

Table 7.  Inductance, capacitance, resistance and voltage p-p (Vp-p) values of detector 2 (D2). 
Length of wire (cm) Inductance (µH) Resistance (R) Voltage (mV) 

0 2.53 0.00 0.0 
10 3.95 0.00 4.0 
20 4.00 1.10 11.2 
30 4.11 1.05 17.3 
40 4.50 0.88 13.2 
50 4.48 0.78 18.3 
60 4.80 0.58 22.4 
70 4.97 0.67 23.8 
80 5.15 0.70 24.6 
90 5.18 0.78 25.7 

100 5.26 0.90 27.7 
 

 



ISSN: 2580-0817 Journal of Mechanical Engineering Science and Technology 67 
 Vol. 1, No. 2, November 2017, pp. 61-68 

 Muhammad Hanis Bin Zakariah1et.al (Development of a Ferrite-Based Electromagnetic) 

 
Fig. 11. Graph pattern resistivity values from D2 

 

Fig. 12. Graph pattern Vp-p Values from D2 

 
Fig. 13. Graph pattern for inductance values from D2 

 
The results of magnetic after-effect lapsed time measurements conducted in this work  shows that 

D1 had a higher lapsed time than D2. It took more than 15 minutes to have Vp-p decreased to zero 
value when the EM wave was switched off. It significantly affected the performance of the D1 even 
though it had a high sensitivity. D2 took 2 seconds to return to  a zero voltage. One important 
mechanism to result in a short lapsed time for detector is to avoid incoming continuous 
electromagnetic wave to pile up.  

IV. Conclusions 
We have constructed a novel ferrite-based EM wave detector for SBL application. From the two 

experiments conducted, we found that the sensitivity of D1 was much higher than D2 by 61%. On 
the other hand, D2 had a lower lapsed time than D1, making it an important aspect for SBL 
application. 

Acknowledgement 
The author wishes to thank the SBL group of Universiti Teknologi PETRONAS for providing 

the facilities and all colleagues who have previously provided technical support. We appreciate 
ACME Ferrite Products Sdn. Bhd who has given support in provideing Ferrite products used in this 
experiment. 

References  
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F.N Kong. Remote detection of hydrocarbon filled layers using  marine controlled source 
electromagnetic sounding. EAGE 64th Conference &  Exhibition, Florence, Italy (2002). 

[2] GEO ExPro (June 2004) The same PRINCIPLE as in borehole logging (pp. 28-30).  
[3] X C.Halfdan, GEO ExPro Proving the concept(June 2004). 



68 Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
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 Muhammad Hanis Bin Zakariah1et.al (Development of a Ferrite-Based Electromagnetic) 

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