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www.etasr.com Kanona et al.: A Review of Ground Target Detection and Classification Techniques in Forward … 
 

A Review of Ground Target Detection and 
Classification Techniques in Forward Scattering 

Radars 
 

Mohammed E. A. Kanona 
School of  

Telecommunication  
Future University  
Khartoum, Sudan 

mohammedkanona@gmail.com 

Mohamed Ghazli Hamza 
School of 

Telecommunication  
Future University  
Khartoum, Sudan 

mohghazli@gmail.com 

Ashraf G. Abdalla  
School of 

Telecommunication  
Future University  
Khartoum, Sudan 

agea33@yahoo.com 

M. K. Hassan 
Faculty of Electrical 

Engineering  
Universiti Teknologi 

Malaysia, Johor, Malaysia 
memo1023@gmail.com 

 
 

Abstract—This paper presents a review of target detection and 
classification in forward scattering radar (FSR) which is a special 
state of bistatic radars, designed to detect and track moving 
targets in the narrow region along the transmitter-receiver base 
line. FSR has advantages and incredible features over other types 
of radar configurations. All previous studies proved that FSR can 
be used as an alternative system for ground target detection and 
classification. The radar and FSR fundamentals were addressed 
and classification algorithms and techniques were debated. On 
the other hand, the current and future applications and the 
limitations of FSR were discussed. 

Keywords-neural network; PCA; Z-score; target classification; 
recognition; forward scattering radar 

I. INTRODUCTION  
Radar systems and stations are used for detecting various 

objects in space and establishing their current position, as well 
as determining velocities and trajectories for moving objects 
[1]. From the basic point of view, this is achieved by 
transmitting an electromagnetic (EM) wave from the 
transmitting antenna. If the target is located within the radar 
coverage area, the wave will be reflected back to the receiving 
antenna [2]. There are different types of radar systems, based 
on the transmitter-receiver topology: (a) the monostatic radar, 
where the transmitter and the receiver are spatially combined, 
and (b) the bistatic radar which consists of a single transmitter 
and a single receiver which are separated by a distance, 
comparable to the maximum range [1]. A Forward scattering 
radar (FSR) is a special state of bistatic radar [3], designed to 
detect and track targets moving in the narrow region along the 
transmitter-receiver base line. Its most attractive feature is radar 
cross section (RCS) which considers the target’s physical cross 
section, the wavelength, the shape of the target’s surface. A 
basic comparison to the traditional monostatic radar can be 
found in [4], whereas probably its most important feature is its 
robustness against stealth technology [5]. Moreover, the FSR 
receiver can utilize radiation from non-cooperative transmitters 
without revealing its location. In a hostile environment this is 
highly desirable as the receiver may be used covertly. All these 

advantage features created a ‘come back’ interest to FSR. In 
addition, FSR can be used for target classification, requires 
relatively simple hardware and has a long coherent interval of 
the received signal. This is the consequence of the loss in range 
resolution [6-7]. On the other hand, the FSR presents a 
conservative class of systems which have a number of 
fundamental limitations, that include the absence of the range 
resolution and operation within the narrow angles. This 
therefore requires the target to be very close to the transmitter-
receiver baseline and the radar loses its ability to measure the 
range when the target crosses the base line.  

II. PREVIOUS AND RELATED WORKS 
Some of the main literature devoted to the FSR is given in 

[8, 9]. Generally, there is a lack of recent publications on FSR. 
Earlier publications, pertaining to the forward scattering, were 
devoted to estimating the RCS of an object at the forward 
scattering. Among others, [5] provides a theoretical analysis 
and various experimental results to prove that the RAM 
coatings did not impose any effect on forward scattering when 
applied on highly conducting objects which were larger than 
the wavelength of the carrier. Nevertheless, the advantages of 
the FSR became known much later. These included the 
increase in the RCS of the object at the forward scattering. In 
[4], author presented a fast and simple approach for estimating 
the effective forward scattering RCS for the different targets at 
various operating frequencies. This was followed by [10], in 
which authors experimentally confirmed that the RCS, at 
forward scattering, was bigger than the one in the monostatic 
case by 30-40 dB, depending on the frequency of the carrier. 
Authors in [11] discussed target detection and estimated the 
detection zones at forward scattering. They showed that the 
detection zone of a FSR was dependent on the type of the 
object and its flight trajectory. They calculated the bistatic RCS 
of the objects, related to the XY Cartesian co-ordinates to 
estimate the detection zones. Authors in [12] on the other hand, 
suggested that the detection is always lost at zero Doppler. This 
area is known as the ‘dead zone’. Authors in [1] suggested that 
the areas worthy of investigation are the system issues of the 



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www.etasr.com Kanona et al.: A Review of Ground Target Detection and Classification Techniques in Forward … 
 

FSR. These include system configurations and system 
parameters, such as the operating frequencies, power levels, 
and baseline distance. All that delayed the deployment of FSR 
in practical applications.  

A. Target Detection in FSR 
Authors in [13] discussed the FSR technology, the current 

and possible applications and the limitations of FSR in a 
feasibility study to the automatic ground target detection and 
classification. Also, the extraction of features from the radar 
measurements was introduced. Authors proved that the FSR 
system has a huge potential to be used as an alternative for 
ground target detection and classification based on PCA as 
feature extraction and the classification algorithm (k-nearest 
neighbor classifier) by a real experiment of three vehicles 
carried out on a public road. Authors in [14, 15] touched the 
problem of extracting the Doppler signature in different 
interference environments by using Hilbert transform and 
wavelet technique in order to predict the existence of target. 
Two experimentations have been done to collect the FSR signal 
under high clutter. The proposed method gave a good result 
with some reservations of wavelet issues. Soon after, authors in 
[16, 17] studied the effect of clutter on the automatic target 
classification (ATC) accuracy in FSR. It was shown that using 
conventional clutter-uncompensated ATC system can achieve 
high target classification accuracy at high SCR only, but the 
accuracy drops significantly with decreasing SCR. The 
employment of clutter-compensated ATC system is shown to 
improve significantly the classification accuracy at low SCR. 
Authors in [18] continued in the same field with new 
improvements in the existing method proposed in [14, 15] by 
considering a rough environment (receiver and surrounding 
noises). Results showed that target detection using a Hilbert 
transform is applicable only for certain conditions but target 
detection employing the wavelet technique is more robust 
against clutter and noise. An inclusive comparison of various 
wavelet threshold selection rules for different types of wavelet 
filters and levels of decomposition is conducted to study the 
effect on target detection with FSR. Two sets of field 
experiments were carried out to validate the proposed method, 
and target signals under the influence of large clutter were 
successfully detected using the proposed method with a 
confidence level exceeding 75%. Then authors in [19] 
implemented the Haar and Meyer wavelet technique in FSR 
which gives more detailed scales and variation information 
from the measured signals. The results from the wavelet 
technique showed that they could find the similarity between 
signals of each target and dissimilarity between different 
targets. 

Authors in [21] investigated accurate signal modeling for 
detecting moving targets in FSR by modifying the existing 
model algorithm by using numerous simulations. They claim 
that all the existing signal models and algorithms are built 
based on the assumptions that the baseline is long, diffraction 
angle is small and velocity direction of the target is 
approximately perpendicular to the baseline, the ground-based 
FSR system is characterized by short baseline and large 
diffraction angle and the velocity direction of the target is not 
always perpendicular to the baseline. Therefore in many cases, 

the above assumptions introduce significant errors to the results 
in the ground-based FSR. In the light of the ground-based FSR 
system, the signal model and imaging algorithm in traditional 
SISAR imaging technology are modified and gave good 
results. Authors in [22] state that, the received signal in FSR 
depends on the target’s electrical size and trajectory, which are 
unknown a priori. As a result, in practical situations, it is 
impossible to obtain the accurate reference function at the 
reception side. That’s why they proposed a signal processing 
algorithm which includes the construction of the adaptive 
reference functions and the identification of target velocity and 
observation time by the adaptation of an optimal filter (quasi-
optimal). They tested the algorithm performance under 
practical motion trajectories such as different motion directions 
and baseline crossing points, which indicates the effectiveness 
of the proposed algorithm in a practical case for FSR. As result 
they found that the proposed methods are suitable for the 
identification of target parameters, and in particular when 
observing target’s time and speed. By knowing those 
parameters the possibility to obtain accurate target recognition 
rises. 

Authors in [23] discussed FSR cross section of different 
target specification by conducting a simulation for analysis of a 
multi-car model. The study showed the effects of different 
target specifications on RCS radiation pattern at different angle 
for each frequency. Novel studies were in [24, 25]. Authors 
used GPS radio shadow instead of previous FSR models in 
order to build a passive FSR system. Investigation on different 
moving objects was introduced. The results showed that from 
FS-GPS radio shadows of different objects, information about 
the parameters of the object (size, speed and direction of 
movement, distance to the receiver) can be extracted from the 
width, shape and length of the received FS shadow. The 
occurrence of FS shadow is essential physical phenomena, 
which can be used to extract some useful information about the 
objects that create it. In [26], authors proved the forward 
scattering GPS radio shadows system can be used for detecting 
road vehicles in urban environment. Authors in [27] followed 
the previous study of target shadow with the practical aspects 
of the target profile reconstruction in a single node ground-
based FSR system and discussed the target return signal for 
three different cars measured in real outdoors environment. The 
study proved that modeling approach can be successfully used 
for simulation of the Doppler phase history, which is required 
in the procedure of complex envelope extraction. The similarity 
of the reconstructed and original profiles demonstrates that 
TSPR delivers results suitable for both visual interpretations of 
target profile and ATC. 

B. Classification Techniques in FSR 
In [2, 28-30], it was shown that FSR can be effectively used 

for ground target detection, and in particular automatic vehicle 
recognition and classification using different techniques and 
scenarios. Researchers classified four different types of 
vehicles into categories based on their sizes and types at 
frequency 1 GHz in ideal case scenario where the vehicles are 
crossing the baseline perpendicularly. In order to perform the 
classification, the combination of principal component analysis 
(PCA) and k-nearest neighbor (KNN) was proposed. Obtained 



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results showed that good vehicle classification performance can 
be achieved. Authors in [31] worked on the evaluation of a 
network of forward scattering (FS) radar micro sensors for the 
detection and classification of ground targets based on the 
findings of [8]. The system power budget was operating in line 
of sight (LOS) conditions. It was evaluated at both theoretical 
and experimental level in terms of power budget analysis and 
resolution. Authors demonstrated that an excellent resolution is 
achievable. The potential resolution of the system is equal to 
the target’s horizontal dimension. The dynamic range of the 
system is also shown to be very high. In addition, a number of 
practical targets were considered as simulation examples over a 
wide range of radar carrier frequencies. In [29], authors proved 
that FSR system has a huge potential to be used as an 
alternative system for ground target detection and 
classification. Authors in [32] proposed another solution based 
on using vehicle height and length and height profiles obtained 
by a microwave (MW) radar sensor. A precise feature vector 
can be extracted, and simple deterministic algorithms can be 
applied to determine the vehicle class. Field trials using a 
spread-spectrum MW radar sensor system operating on these 
principles have been carried out. They confirmed that accurate 
classification of a large number of vehicle classes can be 
reached. 

Authors in [33] used image technique formulation to obtain 
the electric field integral equations (EFIEs) in order to classify 
cylindrical targets from their ultra wide-band radar returns. 
Then, the EFIEs were solved numerically by the method of 
moment (MoM). Because of the wide frequency range of the 
ultrawide-band radar signal, the database to be used for target 
classification becomes very large. To deal with this problem 
and to provide robustness, wavelet transform was utilized. 
Application of wavelet transform significantly reduces the size 
of the database. The coefficients obtained by wavelet transform 
are used as the inputs of artificial neural networks (ANNs). 
Then, the actual performances of the ANNs were investigated 
by receiver operating characteristic (ROC) analysis. Therefore, 
the compressed inputs of the ANNs were determined and a 
dataset was formed. RBF, GRNN and MLP were investigated 
in this work. According to the testing and training rates, the 
best classifier is the MLP. To support this result, sensitivity and 
specificity values and the ROC curves were obtained and it was 
observed that MLP was better. Authors in dealt with a new 
system that uses neural network(NN)-based methodology with 
various types of training algorithms. It reiterates the uniqueness 
and the ability of the neural network implementation to 
accurately classify unknown vehicle signature on the available 
training data, the input of NN is defined as the vehicle length 
and back-propagation NN (BPNN) was used as a NN model. 
The paper proves that NN is suitable to be used as a classifier 
since the classification accuracy exceeds more than 90%. 
Authors in [35] on the other hand, proved the potential and 
utilization of NNs by comparing the KNN classifier and the 
conventional method (PCA) with the proposed. Results showed 
that NNs can be effectively employed in FSR as an automatic 
classifier. After implementing multi-layer perceptron (MLP), a 
BPNN trained with three back-propagation algorithms gave 
very promising results in vehicle recognition and vehicle 
categorization. 10% of overall data was misclassified in vehicle 

recognition and only 2% of overall data was misclassified in 
vehicle categorization. The same classification method was 
applied in [14, 36], but with different trajectory known as angle 
of detection. Theoretically, target’s trajectory is one of the 
factors affecting the target’s signature which contributes 
towards the poor performance of the classification system. 
Hence, by using multiple sensors, the discrepancies in 
classification performance could be reduced. Later, the same 
classification system has been tested at low frequencies: Ultra 
High Frequency (UHF) and Very High Frequency (VHF) 
bands [37]. The paper proved that a good classification 
performance can be obtained even at low frequency. 

Authors in [38] proposed a novel ground vehicle 
classification approach using unmodulated CW radar. The 
radar was set up to look forward down to the road. Vehicles 
were modeled as body targets composed of multiple scattering 
centers. Analysis showed that the spatial distribution of 
scattering centers can be derived from the Doppler signature of 
radar echo. Hough transform was performed to estimate the 
distribution which was then used for classification. In 
experiments, vehicles were classified into three types at an 
average accuracy of 94.8%. Authors in [39, 40] designed and 
developed three novel, distinct automatic target recognition 
(ATR) methods. For the classification they divided the 
observed targets into predefined classes (extremely randomized 
trees or subspace methods). A key feature of the approach was 
the breaking of the recognition problem into a set of sub-
problems by decomposing the parameter space, which consist 
of the frequency, the polarization, the aspect angle and the 
bistatic angle, into regions and build one recognizer for each 
region. Authors in [41] claimed that all previous studies did not 
consider a rough environment analysis in ground target 
classification systems and all experiments have been on ideal 
environment which significantly effects the classifier output. 
After adding simulation noises to the FSR signal output NN 
was used as classifier. As result it was found that classification 
using an ANN is robust against noise to a certain extent of 
noise. They developed an enhanced classification process in 
[42]. However the performance of the classification system was 
still below satisfactory level especially under the influence of 
external factors such as clutter [16], target trajectory 
uncertainties [43] and features used as the input to the 
classifier. 

Authors in [44] addressed the importance of feature 
extraction process in the FSR system by evaluating manual and 
automatic reduction techniques (PCA and Z-score). The main 
objective of this study was to analyze the most suitable feature 
extraction algorithm to classify ground vehicles based on their 
physical size. They continued in [45, 46] by improving the 
classification accuracy by the combination of Z-score and NN. 
It was shown that as the number of features increases, the 
classification accuracy increases. The highest percentage of 
classification accuracy can be achieved when using a NN5 
system. Authors in [47] used LTE signal as a source for passive 
bistatic radar (PBR) for detection and location of ground 
moving targets depending on bistatic RCS. Conventional 
processing was used as classification approach. They 
performed simulations using computer simulation technology 
(CST) microwave studio. The simulation results showed that 



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the large area of ground moving target, had better outcome 
compared to other ground moving targets which is compatible 
with Babinet’s principle, which declares a target of physical 
cross-sectional area is proportionate to RCS. In [48], same 
authors rolled in their previous study but this time detected 
humans instead of vehicles. Real experiments were done by 
testing and evaluating different human sizes. It was discovered 
that the PSD of the individuals are inversely proportional to 
their heights. In PCA, data of the individuals show a good 
convergence in terms of their respective groups. Authors in 
[49, 50] proposed a passive FSR system that can exploit the 
peculiar advantages of the enhancement in forward scatter 
radar cross section (FSRCS) for target detection and 
recognition using LTE signals. This paper illustrates the first 
classification result in the passive FSR system. The great 
potential in the passive FSR system provides a new research 
area in passive radar that can be used for diverse remote 
monitoring applications. In [51], authors presented the latest 
feasibility studies and experimental results from using LTE 
signals in PBR applications. Details are provided about aspects 
such as signal characteristics, experimental configurations, and 
SNR studies. Six experimental scenarios were carried out to 
investigate the detection performance of the proposed system 
on ground-moving targets. The detection ability was 
demonstrated through the use of a cross-ambiguity function. 
The detection results suggested that LTE signals are suitable as 
a source signal for PBR. 

III. CONCLUSION 
This paper presents a review of target detection and 

classification in FSR and its advantages over other types of 
radar configuration. It is generally accepted that FSR can be 
used as an alternative system for ground target detection and 
classification. Further, recent research focused on the 
application of different classifiers to accurately classify 
unknown vehicle signatures. Moreover, feature extraction was 
addressed, especially PCA and Z-score to improve 
classification accuracy. The area of ground vehicle 
classification is very interesting, that’s why intensive studies 
have been conducted in the last few years looking for 
alternatives to old systems, using FSR theory to reduce the cost 
and to make use of the existing transmitted signals. Therefore, 
GSM, LTE, GPS and FM were tested for detection and 
recognition of vehicles and humans as well using the same 
classification techniques. However, a number of problems are 
still unsolved, including the choice of optimum frequency, a 
more precise and intelligent speed estimation algorithm plus 
the absence of the range resolution and operation within the 
narrow angles. Another set of problems is the choice of the 
feature extraction before injecting the signature into the 
classifier. Future research will focus on using artificial 
intelligence, especially NNs with bigger databases and feature 
extraction techniques as pre-processing to improve the 
classification system in order to implement automatic 
classification, in order to lead to wider use of FSR in other 
areas.  

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