Crocco .pdf


559

ANNALS OF GEOPHYSICS, VOL. 46, N. 3, June 2003

GPR prospecting in a layered medium 
via microwave tomography

Lorenzo Crocco and Francesco Soldovieri
Istituto per il Rilevamento Elettromagnetico dell’Ambiente (IREA), CNR, Napoli, Italy

Abstract
The tomographic approach appears to be a promising way to elaborate Ground Penetrating Radar (GPR) data in 
order to achieve quantitative information on the tested regions. In this paper, we apply a linearized tomographic 
approach to the reconstruction of dielectric objects embedded in a layered medium. The problem is tackled with 
reference to a two-dimensional geometry and scalar case when data are collected over a  linear domain with finite
extent. In particular, in order to increase the amount of independent available data, a multi-frequency/multi-view/
multi-static measurement configuration is considered. With reference to stepped-frequency radar, this means that 
for each working frequency and for each position of the transmitting antenna (moved along a linear domain), 
the electric field scattered by the buried targets is measured in several locations along the same linear domain. 
The proposed inversion approach is based on the Born approximation and a regularized solution is introduced 
by means of the Singular Value Decomposition (SVD). The problem of determining the optimal measurement 
configuration (in terms of number of frequencies and number of transmitting and receiving antennas) is also tackled 
by a numerical analysis relying on the Singular Value Decomposition (SVD). Numerical examples are provided 
to assess the effectiveness and robustness of the proposed approach against noise on data.

Mailing address: Dr. Lorenzo Crocco, Istituto per il 
Rilevamento Elettromagnetico dell’Ambiente (IREA), 
CNR, Via Diocleziano 328, 80124 Napoli, Italy; e-mail: 
crocco.l.@irea.cnr.it

Key  words  GPR – microwave tomography – inverse 
scattering – ill-posed problems

1.  Introduction

Ground Penetrating Radar (GPR) is widely 
employed in civil engineering, shallow sub-
surface prospecting applications and archae-
ology (Daniels, 1996) since it allows non inva-
sive diagnostics of the probed domain in a fast 
and simple way.

GPR works by emitting a modulated el-
ectromagnetic pulse into the ground and by 
recording the strength of the echo produced by 
the interaction between the impinging waves and 

the buried objects received at the air-soil interface 
in a monostatic or bistatic configuration. In the 
former case, the locations of the transmitting and 
the receiving antennas are coincident, whereas 
they are different in the latter case. By moving the 
antenna along a selected profile above the ground 
surface, a two-dimensional plot (radargram) is 
obtained in which the delay time of the recorded 
echoes (which can be related to the depth of the 
underground reflectors) is drawn versus the 
antenna position (Daniels, 1996). 

This fast and simple operating mode is, 
however, able to survey only the presence 
and the location of the buried object but not 
its characteristics, unless additional a priori
information is provided. Moreover, since it 
is based on the assumption that the velocity 
of the investigating wave is constant, it may 
often give misleading results. Finally, the in-
terpretation of the radargrams is itself a dif-
ficult task which encompasses the ability and 
expertise of the user and requires the availability 



560

Lorenzo Crocco and Francesco Soldovieri

of a priori information about the domain under 
investigation.

A tomographic approach represents a possible 
way to overcome these limitations as it makes it 
possible to achieve quantitative reconstruction
of the domain under investigation, in terms of 
location, shape and chemical/physical properties 
of the buried targets (Deming and Devaney, 
1997). In this case, the problem at hand amounts 
to determining the dielectric and conductive 
properties of the probed domain starting from the 
knowledge of the electromagnetic field scattered 
under the incidence of known impinging fields.
To this aim one has to perform the inversion of a 
pair of coupled integral equations which govern 
the electromagnetic scattering. Such an inversion 
is not a simple task (Colton and Kress, 1992) 
since it amounts to solving a non-linear ill-posed 
inverse problem. Indeed, due to the properties 
of the kernel of the integral equation relating 
the unknowns to the scattered field data (Bucci 
and Isernia, 1997; Pierri and Leone, 1999), in 
the presence of uncertainties on the data only 
a finite amount of independent information 
about the unknowns can be achieved. From a 
mathematical point of view, this means that a 
proper regularization strategy has to be adopted  
to restore the well-posedness of the problem 
(Bertero and Boccacci, 1998).

In addition, the nonlinear relationship 
between the data and the unknowns makes 
it very difficult to solve the problem, usually 
cast as the minimization of a non quadratic 
cost functional. Due to the large number of 
unknowns one usually has to deal with, stochastic 
optimization tools cannot be exploited and so 
deterministic minimization techniques have 
to be adopted (Isernia et al., 1997; Kleinman 
and van den Berg, 1993). Since convergence of 
deterministic approaches depends on the starting 
guess, the minimization can get stuck in a local 
minimum of the cost functional which actually 
represents a «false solution» of the problem 
(Isernia et al., 1997; Leone et al., 2001). The 
local minima problem leads to the necessity of 
making the number of the searched parameters 
as low as possible, or in an equivalent way to 
keep as high as possible the ratio between the 
amount of independent data and the number 
of the unknowns to be determined (Isernia 

et al., 2001). This requires availability of a priori
information about the features of the unknowns 
and entails constraints on the extent of the probed 
domain.

Another class of solution algorithms is instead 
based on the adoption of linear approxima-
tions of the electromagnetic scattering (see, for 
instance, Deming and Devaney, 1997; Wang 
and Oristaglio, 2000; Pierri et al., 2001, 2002a). 
These linearized inversion algorithms require 
lower computational cost with respect to the 
nonlinear ones and no local minima problem 
arises for the corresponding functionals. The 
above factors make the linear inversion algorithms 
suitable in several applications concerning the 
diagnostics of large probed domain and allow 
real-time processing. Conversely, the adoption 
of approximate models of the electromagnetic 
scattering, introduces several limitations on the 
set of unknown functions which can be dealt with 
(Pierri et al., 2001).

In microwave tomography, the linearization 
is usually achieved by means of the Born 
Approximation (BA), which consists in ap-
proximating the total electric field inside the 
investigation domain with the incident one, i.e.
the scattering object is a small perturbation with 
respect to the host medium. This assumption 
entails some constraints on the extent of the 
buried objects (which must be small with 
respect to the investigating wavelength) and on 
the difference between the dielectric properties 
of the objects and those of the background me-
dium (which must be as low as possible) (Slaney 
et al., 1984).

In addition, also within the validity of the 
Born model, further constraints arise about 
the unknowns which can be dealt with. These 
limitations concern their allowable spatial va-
riations and are due to the filtering effect of the 
relevant linear operator relating the unknowns 
to the scattered field data (Bucci et al., 2001a; 
Pierri et al., 2002a,b).

To this end, the Singular Value Decom-
position (SVD) of the relevant linear compact 
operator (Bertero and Boccacci, 1998) provides 
a powerful tool to examine the amount of 
independent information carried by data, to 
discuss the class of retrievable unknowns, to 
determine the achievable spatial resolution limits 



561

GPR prospecting in a layered medium via microwave tomography

in the retrieved tomographic images (Bucci et al., 
2001a; Pierri et al., 2002a,b) and to give a stable 
solution of the problem.

In this paper, we apply the BA linear approach 
to the reconstruction of the spatial map of the 
dielectric and/or conductive properties of an 
investigation domain in the case of a layered 
medium. In particular, we consider a three-
layered medium and inquire about the dielectric 
and conductive characteristics of an investigation 
domain completely embedded in the second 
layer. Such a scheme is representative of several 
realistic cases such as for instance masonry 
diagnostics and prospecting of the shallower 
layers of soil (Crocco et al., 2002). The two-
dimensional and scalar case is tackled with a 
filamentary excitation and the data are collected 
according to a multifrequency/multiview/multi-
static strategy. As such, for each working fre-
quency and for each position of the source, the 
data are measured in several locations along a 
linear domain of finite extent and very close to 
the first interface. The only a priori information
about the problem regards the location and the 
extent of the investigation domain within which 
the objects are supposed to reside. 

2.  The mathematical model

The reference situation is shown in fig. 1. 
The first region is homogeneous with relative 
dielectric permittivity e1 and conductivity s1.
The second layer has extent equal to d and is 
homogeneous with relative dielectric permittivity 
e2 and conductivity s2. The third region is ho-
mogenous with relative dielectric permittivity 
e3 and conductivity s3. The complex equivalent 
relative permittivity in each layer has an explicit 
dependency on frequency given by

  
       (2.1)

e0   being the free space dielectric permittivity and 
w the pulsation. The magnetic permeability is 
everywhere equal to that of the free-space, µ0.

We suppose that infinitely long cylindrical 
objects having cross sections invariant with 
respect to the z-axis are embedded in the second 

layer and that their cross sections are contained 
within an a priori fixed square investigation 
domain D, completely embedded in the second 
layer. The unknowns of the problem are the 
spatial distribution of the relative dielectric 
permittivity and that of the conductivity over 
the investigation domain D.

The source of the incident field is a filamentary 
z-directed electric current (TM polarization), of 
non finite extent and constant along the z-axis,
which radiates at different frequencies. Such a 
source is located in the first layer and is moved 
along the line G parallel to the first interface 
and located very close to it. In order to collect 
multifrequency/multiview/multistatic data, for 
each working frequency and at each position 
of the source the electric field scattered by the 
buried targets is measured in several locations 
along G.

It is worth noting that such a set-up can 
be practically realized by using only one pair 
of antennas. As a matter of fact, exploiting a 
«synthetic array» strategy, one antenna acts as 
transmitter and the other one, which acts as re-
ceiver, is moved along the measurement line in 
the desired positions. By repeating this procedure 
for different locations of the transmitting antenna, 
one can achieve the desired set of data.

Under the above assumptions, the electro-
magnetic scattering phenomenon at hand is 
described by a two dimensional scalar model and 

ε ω ε σ ωεi
eq

i ij( ) = − / 0

Fig. 1. Geometry of the problem.



562

Lorenzo Crocco and Francesco Soldovieri

it is governed by the following pair of integral 
equations (Chew, 1995)

   
      

         (2.2a)
  
      

  
      

      (2.2b)

where the time-factor exp ( jwt) has been omitted, 
k

2
is the (complex) wavenumber in the second 

medium, Einc, E and ES are the incident field in 
D (i.e. the field in the absence of the object), the 
total field induced inside the investigation domain 
D and the scattered field on G, respectively; r, rt,
rr denote the generic point in the domain D, the 
generic location of the source and the generic 
measurement point, respectively. 

The quantities g21 and g22 are the Sommerfeld-
Green’s functions pertaining to the considered 
geometry and their expressions, as well as that of 
the incident field are reported in Appendix. 

The contrast function c relates the searched 
(complex) permittivity (defined in the domain 
D) to that of the background (medium 2) and is 
defined as

       
      (2.3)

where

          (2.4)

Such a complex function changes with fre-
quency and this does not allow to consider it 
as a convenient unknown in the multifrequency 
case. However, assuming a priori that e

i
and s

i

in eq. (2.1) as well as e
D

and s
D

in eq. (2.4) are 
independent of frequency, we can introduce a pair 
of frequency independent real functions

  
          (2.5)

wm being the maximum working frequency. These 
functions are simply related to c

  
          (2.6)

and in what follows we will assume them as 
the actual unknowns of our inverse problem. 
By so doing we are able to deal with frequency 
independent unknowns, De and Ds, without 
neglecting the dispersive nature of the problem.

3.  The linearized tomographic approach 

In its general formulation, see eqs. (2.2a,b), 
the problem we are dealing with is non-linear. 
However, in some cases it is possible to describe 
the problem by means of an approximated 
model.

The Born approximation (Slaney et al.,1984)
consists in neglecting the mutual interactions 
between the objects and amounts to assuming 
the internal field E in D equal to the unperturbed 
one. This allows a considerable simplification
since the electromagnetic scattering is modeled 
by means of a single linear integral equation.

When the targets are embedded in a lossy 
medium, a large number of cases can be mod-
eled by means of the BA (Bucci et al., 2001b), 
since the presence of losses smoothes multiple 
scattering effects. Considering that in masonry 
diagnostics as well as in subsurface prospecting 
involved media are usually lossy, we will con-
sider the BA in the following. 

Accordingly, the mathematical model is 
given by

      

      
          (3.1)

and the problem can be cast as the inversion 
of the linear operator given by eq. (3.1) and 

χ ω
ε ω
ε ω

,
,

r
r

( ) =
( )
( )

−D
eq

eq
2

1

ε ω ε σ ω εD
eq

D Dj, / .r r r( ) = ( ) − ( ) ( )0

∆ ∆ε ε ε σ
σ σ

ω ε
= −

−
D

D

m

2
2

0

,  =

χ ω
ε

ε
ω
ω

σ, r r r( ) = ( ) − ( )



1

2
eq

mj∆ ∆

E k
E g

j
s

D

r r
r r r r

r t
t r' ', ,

, , , ,

/
ω

ω ω
ε σ ωε

( ) = ( ) ( )
−

×∫22 21
2 2 0

inc

j
dmr r r' ' 'ε

ω
ω

σ× ( ) − ( )





∆ ∆

E E k E
D

r r r r r r, , , , , ,t t t'ω ω ω( ) − ( ) = ( ) ⋅∫inc 22

E k Es
D

r r r r rr t t' ', , , , ,ω ω χ ω( ) = ( ) ( ) ⋅∫22

g d Dr r r r r rt, , , ,' ' 'χ ω ω⋅ ( ) ( ) ∈ ∈22 Γ

g dr r r r rr r t' ', , ,ω⋅ ( ) ∈21 Γ



563

GPR prospecting in a layered medium via microwave tomography

defined as

LDB: xŒX �L
2(D) ¥ L2(D)ÆE

s
ŒY�L2(G ¥ G ¥ F).

          (3.2)

In eq. (3.2) X is a subspace containing all the 
pairs of functions x = (De, Ds) and the data space 
Y is a subspace containing the scattered fields
corresponding to all possible measurement 
positions over G, all possible source positions 
over G and to the frequency band F.

Due to the properties of its kernel, LDB is 
a compact operator, so that its inversion is an 
ill-posed problem and the necessity of restoring 
well-posedness arises (Bertero and Boccacci, 
1998). Therefore  a suitable regularization scheme 
has to be adopted to set up a stable and reliable 
solution.

A convenient tool to achieve a regularized 
inversion is provided by the SVD of the operator 
LDB, which defines a triplet σ νn n n nu, ,{ } =

∞

0
such

that

LDB(un) = snnn, LDB
+(n

n
) = s

n
u

n
       (3.3)

wherein LDB
+ is the adjoint operator of LDB,

σ n n{ } =
∞

0
denotes the sequence of the singular 

values ordered in non increasing sequence and 
u

n
and v

n
form the basis for the space of the visible 

objects (that is the objects which can be recovered 
by the error-free data) and for the closure of the 
range (that is the space of the noise-free data) of 
the operator, respectively. 

Exploiting the SVD of the relevant operator, 
the formal solution of integral eq. (3.1) can be 
cast as

  
          (3.4)

where <.,.> denotes the scalar product in the 
data space. 

The compactness of LDB entails that the 
sequence of the singular values asymptotically 
decays to zero (Bertero and Boccacci, 1998). 
Therefore the ill-posedness of the inverse problem 
given by eq. (3.1) immediately appears: indeed, in 
the presence of noise on data, the contributions to 
the solution related to the singular values closer 

(*) The model error is the discrepancy between the 
actual scattered field data and those that would result 
according to the BA.

to zero will be strongly corrupted by noise and the 
result of the inversion will become unstable.

A simple way to tackle such an instability 
consists in truncating the expansion (3.4) to 
those terms that are not overwhelmed by noise. 
Therefore we assume as a regularized solution 
of our problem the one obtained by means of the 
truncated SVD expansion 

  
       

       (3.5)

By restricting the solution space to that span-
ned by the first N + 1 singular functions, this 
regularized solution is stable with respect to 
errors on data. However, since it is achieved by 
considering only a reduced number of terms in eq. 
(3.4), this procedure will lead to an approximate 
representation of the sought unknown. Therefore, 
the choice of the index N represents a trade-off 
between the accuracy of the solution and its 
stability with respect to noise. Such an optimal 
choice, in its turn, is actually related to the 
estimated level of noise and to the model error 
(*). As a consequence, the optimal choice may be 
a chimera, because the model error depends on 
the unknown scattering object. Lacking definite
criteria to determine such an optimal choice, we 
have chosen in our regularized approach to reject 
the contributions related to singular values 20 dB 
lower than the maximum one.

3.1.  The discretization procedure

The numerical implementation of the in-
version procedure described above is based on 
an equivalent matrix formulation of the problem 
in which only real vectors are involved. 

As a first step, one has to discretize the 
unknown parameters within the investigation 
domain D. In order to satisfy the criteria 
outlined in Richmond (1965), the pair of un-
known functions is expanded by using as 
a basis the pulse functions defined within 

x E u
nn

N

s n n= < >
=
∑ 1

0 σ
ν, .

x E u
nn

s n n= < >
=

∞

∑ 1
0 σ

ν,



564

Lorenzo Crocco and Francesco Soldovieri

N
c

¥ N
c

square cells whose side is l / 20 long, l
being the minimum wavelength, thus rendering 
the results of the discretized version of the 
problem very close to those of the continuous 
problem in eq. (3.1). The vector of the unknowns 
is now defined as a column vector of dimension 
2N

c

2, whose first N
c

2 rows contain De, and the 
second N

c

2 rows contain Ds.
A discrete set of measurements N

m
, incident 

fields N
v

and frequencies N
f

is considered, lead-
ing to M = N

m
¥ N

v
¥ N

f
complex data. Therefore, 

the data vector is defined as a column vector of 
dimension 2M, in which the real part of the 
scattered fields (considered at each frequency, 
incident field and measurement point) is stored in 
the first M rows, and the imaginary part is stored 
in the latter M rows. 

By following this procedure one achieves the 
matrix equation:

  
       (3.6)

wherein A, B, C, D are block matrices of 
dimension M ¥ N

c

2, computed by separating the 
discretized counterpart of eq. (3.1) in its real and 
imaginary parts. 

The discretized problem, as stated in eq. (3.6), 
can be now solved by means of the numerical 
SVD applied to real matrices. 

4.  Fixing the measurement set-up via SVD

Besides defining the regularized solution 
of the linear inversion at hand, the SVD can be 
exploited as a tool to fix the number of antennas 
of the measurement set-up and to investigate the 
effect of using a different number of frequencies 
in a given band. 

This can be performed by examining the 
effect of the change in the number and locations 
of the transmitting and receiving antennas on 
the number of the singular values N retained in 
the summation (3.5). According to the choice of 
the above section, we assume N as the number 
of singular values larger than 0.1 times the 
maximum singular value.

The analysis is performed under the sim-
plifying hypothesis of  transmitting and receiving 
antennas uniformly spaced over the observation 
domain. In addition, thanks to the arguments in 
Bucci et al. (2001a), it is convenient to assume 
that the number of transmitter and receiver 
locations is the same. In this way it results 
N

v
= N

m
, that is for each of the N

m
positions of 

the transmitter, N
m

measurement are collected 
(multiview/multistatic configuration).

One can expect that when the number of trans-
mitters and receivers increases, some indepen-
dent information about the unknown is added 
and so the number N of useful singular values 
to be retained in (3.5) increases. However, since 
the available information carried by the scattered 
fields is finite, it is expected that a maximum 
number of antennas exists beyond which the 
addition of further antennas does not change in 
a significant way the number of useful singular 
values to be employed in the reconstruction.

This is a very important point as in any prac-
tical application an increase in the complexity 
of the set-up means increasing costs in terms of 
measurement time and computational burden.

To give an example of how the SVD can 
be usefully exploited to this aim, we have con-
sidered a case typical of masonry diagnostics, 
in which media 1 and 3 are the free space and 
medium 2 is d = 2 m thick and has a relative 
dielectric permittivity of 6 and a conductivity of  
1 ¥ 10 -3 S/m. The investigated domain is 
1 m  ¥ 1 m starting from the first interface and the 
receivers and transmitters are placed on a line G
1 m long placed just above the interface.

The following analysis concerns only the 
relevant linear operator and therefore it does not 
depend on the targets, but only on the geometrical 
characteristics of the investigated domain, the 
background permittivity and the measurement 
configuration.

Firstly, let us consider a single frequency case 
at 300 MHz and determine which is the suit-
able number of antennas. This is performed by 
evaluating the SVD of the matrix defined in eq. 
(3.6) when changing the number of transmitters 
and receivers. Figure 2 shows the behavior of 
the normalized singular values greater than the 
threshold (assumed equal to – 20 dB) in these 
various situations. As can be seen, the number of 

A B

C D






 ⋅







 =

( )
( )











∆
∆

ε
σ

Re

Im

E

E
S

S



565

GPR prospecting in a layered medium via microwave tomography

Fig.  2. Behavior of the normalized singular values of LDB at 300 MHz when changing the number of transmitter 
(and receiver) positions. A suitable choice is N

m
 = 9 (N

v
 = 9).

Fig.  3. Behavior of the singular values of LDB when varying the number of frequency steps in the 100-300 MHz 
band: N

f
= 2 (100, 300), dashed-dotted line; N

f
= 3 (100, 200, 300), dotted line; N

f
= 4 (100, 150, 225, 300), solid 

line; N
f
 = 5 (100, 150, 200, 250, 300), dashed line.



566

Lorenzo Crocco and Francesco Soldovieri

useful singular values remains nearly unchanged 
when varying N

m
from 9 to 13 or more, while it is 

considerably lower when considering N
m

equal to 
5 or less. On the basis of such a simple analysis 
we can then conclude that a suitable choice for 
N

m
 (and hence for N

v
) is 9.

Secondly, by assuming such a number of 
transmitter and receiver locations, we can then 
investigate the effect of the addition of the 
working frequencies in the band 100-300 MHz. 
Figure 3 shows behavior of the singular values 
when increasing the number of frequencies in 
the 100-300 MHz band. First of all, it appears 
than increasing such a number has benefi-
cial effects on the number of singular values. 
However, it also appears that considering more 
than four frequencies does not bring a definite
advantage. In what follows we will assume 
that the data are collected at 100, 200 and 300 
MHz. Although a (slightly) larger number of 
singular values would be achieved considering 
four frequencies, this choice satisfies the need 
of keeping the computational burden as low 
as possible, without dramatically reducing the 
number of singular values.

In conclusion, we have shown that exploiting 
the SVD tool it is possible to simply determine 
the measurement set-up, both in terms of the 
number of antennas and in terms of the number 
of frequencies to consider.

5.  Numerical examples

In this section we will give some examples 
aimed to show the reconstruction capabili-
ties of the proposed inversion approach. The 
reference situation is the one depicted in fig. 1. 
The measurement set-up is designed according 
to the criteria outlined in the previous section 
and considers three equispaced frequencies in 
the band 100-300 MHz. At each frequency, in 
correspondence of each of the nine positions 
of the transmitting antenna, the scattered field
is measured at nine equispaced positions along 
the measurement line G, 1 m long and placed 
very close to the first interface. The investigated 
domain is 1 m ¥ 1 m wide, starting from the first
interface and is embedded in a layer which is 
d = 2 m thick. The dielectric and conductive 

properties of the three media are the same as in 
the previous section.

In all the examples, the data have been 
synthetically generated by means of a forward 
solver which exactly solves eq. (2.2a,b) and then 
corrupted by means of an additive white noise to 
simulate measurement error. 

The aim of these examples is twofold. First, 
we want to show that the proposed approach 
can furnish qualitative information on the in-
vestigated region even when the model error is 
very large. As a matter of fact, unless a very low 
model error is present, it is not possible to a-
chieve a quantitative reconstruction (even in the 
noiseless case) due to the discrepancy between 
the actual (synthetically generated) data and the 
data that would arise from the BA model. Second, 
we want to show how the proposed regularization 
is a robust inversion tool when considering noise 
corrupted data. Therefore, we will show for each 
case the reconstruction achieved in the (ideal) 
case of clean data and that obtained when data 
are corrupted by noise.

In the first example, we consider the problem 
of imaging a rectangular void. Due to the strong 
difference between the permittivity of the target 
and that of the background, the model error is 
quite large (about 100%), and we do not expect 
to achieve a quantitative reconstruction. Figure 
4a shows a comparison between the modulus of 
the (simulated) scattered data at 200 MHz and the 
corresponding field that would result according to 
the BA: as it can be seen the difference between 
the two fields is very large. Figure 4b shows the 
comparison between the clean data and the data 
corrupted with an additive Gaussian noise with 
an SNR of 10 dB, which does not change at the 
various frequencies. By comparing fig. 4a,b one 
can observe that in this case the larger error 
comes from the failure of the BA model.

Several factors affect the model error. Among 
them the difference between the permittivity of the 
target and that of the background plays a major 
role. In table I one can observe how the model 
error varies when changing the permittivity of the 
target (the rectangular void we are considering): 
the void certainly represents a situation in which 
the BA assumptions are strongly violated. 

Another interesting point is the behavior of 
the model error as a function of the working 



567

GPR prospecting in a layered medium via microwave tomography

frequency. In the case of an empty cavity, we 
can observe that the model error decreases with 
frequency, being equal to 118% at 300 MHz, 
96% at 200 MHz and 52% at 100 MHz. This 
can be explained observing that when decreas-
ing the working frequency, the corresponding 
wavelength increases and therefore the electrical 
dimension of the target decreases too. This entails 
that, as long as the working frequency decreases, 
the validity of BA is ensured. 

However, when decreasing the working fre-
quency the amount of independent information 
carried by data decreases (Pierri et al., 2001, 
2002a) and therefore only an approximation 
of the sought unknown with a lower resolution 
can be achieved (Pierri et al., 2002b). This is 
the main reason why frequency diversity is very 

a

b

Fig.  4a,b. Case 1: a rectangular void.  a) Comparison between actual scattered data (solid line) and data that 
would result according to the BA model (dotted line). b) Comparison between clean data (solid line) and data 
corrupted by noise with an SNR = 10 dB (dotted line). The plotted quantity is the modulus of the field at 200 MHz 
for each location of the transmitter and the receiver. 

Table  I. Behavior of the model error when changing the 
value of the target permittivity. The larger the relative 
difference between the background permittivity (e

b
= 6) 

and the target one the larger the model error is.

Target permittivity Model error %

1 116
2 115
3 100
4 69
5 33

5.9 3
7 31
8 59
9 80
10 94



568

Lorenzo Crocco and Francesco Soldovieri

important in microwave tomography approaches. 
As a matter of fact, exploiting multifrequency 
data it is possible to jointly consider data affected 
by a low model error (those pertaining to the 
lower frequency) and data which carry «more» 
independent information (those pertaining to the 
higher frequency). 

In order to show the effect of the model 
error on the reconstruction capabilities of our 
approach, let us first consider the case of clean 
data. Figure 5 plots the modulus of the retrieved 
contrast (evaluated at 200 MHz placing the 
retrieved D e and Ds in eq. (2.6). As expected, 
we cannot achieve a quantitative reconstruction, 
nevertheless the regularized inversion approach 
locates the target properly (but for a small 
misplacement). The effect of the model error is 
also evident as a «ghost» appears in the deeper 
part of the region. This is related to the mutual 
interactions between the target and the sec-
ond interface which are indeed neglected under 
the BA.

In order to prove the stability of our ap-
proach against noise on data, we repeated the 
inversion considering noise corrupted data 
and the modulus of the reconstructed contrast 
function is reported in fig. 6. As can be seen, the 
achieved reconstruction is almost unchanged 
compared to the clean data case, apart for an 
obvious (small) enhancement of the artifacts. 
The inversion procedure is quite fast as it takes 
only a couple of minutes to run on a 200 MHz 
Pentium II computer.

In the second example, we consider the case 
of imaging a conductivity anomaly; the target 
has the same permittivity as the background 
but a slightly different conductivity (9 ¥ 10-3
S/m). While in the previous example the main 
(theoretical) contribution to the scattering data 
was due to D e, in this case the main contribution 
is due to Ds. Due to the small difference be-
tween the conductivity of the target and that 
of the background, a lower model error is 
expected, which indeed is about 13% (and is 
almost constant with frequency). This entails 
that the actual data and the data arising from the 
BA model are very similar; as pointed out by 
the comparison between the two fields at 200 
MHz which is given in fig.7a. On the other hand, 
when comparing clean and noise corrupted data 

(fig. 7b), it appears that in this case the effect of 
measurement error is definitely more relevant 
than in the previous case. Considering the clean 
data first, the modulus of the reconstructed 
contrast is plotted in fig. 8. The target can be 
clearly located and also the quantitative value of 
the contrast is determined with a good accuracy 
(the actual value of the modulus of the contrast 
would be 0.08). 

Also in this case we repeated the test by 
corrupting the data with an additive white noise 
(SNR = 10 dB) and again the achieved result, see 

Fig. 5. Case 1: a rectangular void. Modulus of the 
reconstructed contrast when considering clean data. 
The reference shape is reported as a contour plot.

Fig. 6. Case 1: a rectangular void. Modulus of the 
reconstructed contrast when considering noise-cor-
rupted data (SNR = 10 dB).



569

GPR prospecting in a layered medium via microwave tomography

fig. 9, proves the stability of our approach with 
respect to noise.

In the last example we show the target is an 
empty pipe whose cross-section has a ring shape. 
The pipe has a relative dielectric permittivity of 
7, a conductivity of 1 ¥ 10-3 S/m and it is 10 
cm thick. This case is a quite hard one because 
both D e and Ds contribute to the scattered field,
moreover a large model error (70%) is present due 
to the strong difference between the permittivity of 
void (inside the pipe) and that of the background, 
while at the same time a little difference between 
the pipe and the background is present. In fig.
10 the modulus of the real part of the contrast 
reconstructed from clean data is plotted. Again, 
due to the large model error, no quantitative 
reconstruction is achieved, but the presence of 
the target as well as the «transition» between the 

a

b

Fig.  7a,b. Case 2: a conductivity anomaly. a) Comparison between actual scattered data (solid line) and data 
that would result according to the BA model (dotted line). b) Comparison between clean data (solid line) and data 
corrupted by noise with an SNR = 10 dB (dotted line).The plotted quantity is the modulus of the field at 200 MHz 
for each location of the transmitter and the receiver. 

Fig.  8.  Case 2: a conductivity anomaly. Modulus of 
the reconstructed contrast when considering clean data. 
The reference shape is reported as a contour plot.



570

Lorenzo Crocco and Francesco Soldovieri

shell and inner part of the pipe can be inferred from 
the reconstruction. Finally, in fig. 11 the modulus 
of the real part of the reconstructed contrast when 
considering noise corrupted data (SNR = 10 dB) is 
reported, again proving robustness of the proposed 
approach against noise.

6.  Conclusions

A linearized approach elaborated within 
the framework of the BA for the reconstruction 

of objects embedded in a layered medium has 
been presented. A suitable formulation of the 
problem allowed us tackle the dispersive na-
ture of the scattering problem considering a 
pair of frequency independent unknowns, D e
and Ds. This exploits multifrequency data at 
best.

As shown by several numerical examples, 
the proposed approach produces an efficient and 
reliable solution algorithm. In particular, the 
regularization strategy proves to be very stable 
since results obtained with «clean» and noise-
corrupted data are almost coincident. More-
over, although the assumptions underlying 
the BA model actually limit the class of retriev-
able functions (in terms of the permittivity and 
the extension of the target with respect to that of 
the background as well as in terms of its spatial 
variability), the numerical examples show that 
the approach can provide good (qualitative) 
results also in cases in which the linear ap-
proximation fails. 

The SVD tool has been widely exploited 
in this paper not only to regularize the inverse 
problem, but also to determine which is the 
optimal measurement set-up. As a matter of 
fact, by means of a simple numerical analysis, 
we were able to determine the suitable number 
of measurements to perform and the number of 
working frequencies to consider.

Fig.  9.  Case 2: a conductivity anomaly. Modulus of 
the reconstructed contrast when considering noise-
corrupted data (SNR = 10 dB).

Fig.  10. Case 3: a buried empty pipe. Modulus of the 
real part of the reconstructed contrast when consid-
ering clean data. The reference shape is reported as a 
contour plot.

Fig.  11. Case 3: a buried empty pipe. Modulus of the 
real part of the reconstructed contrast when consid-
ering noise-corrupted data (SNR = 10 dB).



571

GPR prospecting in a layered medium via microwave tomography

Appendix.

The function g21 represents the field generated in the first medium at the location (xp, yp) by a 
filamentary source located at the point (x',y') in medium 2. By relying on the general expression for a 
layered medium (Chew, 1995) one achieves

        (A.1)

wherein k  is the spatial frequency and 

                       (A.2)
  
               

        (A.3)

accounts for the transmission between media 1 and 2 for a given spatial frequency,

        (A.4)

is the reflection coefficient between media i and j for a given spatial frequency and

             
                      (A.5)

is an «equivalent» reflection coefficient which takes into account the multiple reflections at the two 
interfaces.

The function g
22

represents the field generated in the second medium in the location (x, y) by an 
elementary source located in the point (x',y') in the same medium.

Its expression (Chew, 1995) is given by

                  

                 

                  
        (A.6)

wherein H0
(   2) (.) is the zero order second kind Hankel function, D x = x - x', Dy- = y - y' and Dy+ = y + y'.

g x y x y
j

M j y j x x j yp p p p21 21 2 1 2
4

, , , exp exp exp' ' ' '( ) = − ( ) −( )[ ] × −( ) +[
−∞

+∞

∫π τ β κ β

R j d j y d23 2 22exp exp '+ −( ) ( )]β β κ

β ω µ ε ε κi i= −
2

0 0
2 .

τ
β β21 1 2

2
=

+

Rij
i j

i j

=
−
+

β β
β β

.

M
R R j d

2
21 23 2

1
1 2

=
− −( )exp β

g x y x y
j

H x y22 0
2

2
2 2

4
, , , ( )' '( ) =

−
+( ) +−β ∆ ∆

j R M R
j d y j x d23 2 12

2

2 2
2

2exp cos exp− ( ) ( ) ( ) +−
−∞

+∞

∫π β β β κ κ∆ ∆

j M
R j y R j y j d

2

2

2

21 2 23 2 2
4

2exp exp− −( ) + −( ){ + +
π β

β β β∆ ∆ }} ( )
−∞

+∞

∫ exp j x dκ κ∆



572

Lorenzo Crocco and Francesco Soldovieri

By means of the Green-Sommerfeld functions it is also possible to evaluate the incident field in 
the domain D produced by a filamentary current I0 located in the first medium at a distance yt from
the interface

                  

            

                                (A.7)

As can be seen, g21, g22 and the incident field can be interpreted as 1-dimensional Fourier transforms in the 
spatial frequency k and therefore can be efficiently computed by means of Fast Fourier Transforms. 

Some remarks on the solution of the forward scattering problem can be found in Crocco et al.
(2002).

E
j I

M j y j x xt t tinc r r, exp exp( ) = − ( ) −( )[ ] ×
−∞

+∞

∫
ωµ

π
τ β κ0 0 21 2 1

4
'

j y R j d j y dexp exp exp .× −( ) + −( ) ( )[ ]β β β κ2 23 2 22' '

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