Faggioni.pdf


525

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

A realistic inversion algorithm for 
magnetic anomaly data: 

the Mt. Amiata volcano test

Osvaldo Faggioni (1) (2), Nicolò Beverini (1) (3), Fabio Caratori Tontini (1) (3),
Cosmo Carmisciano (1) and Iacopo Nicolosi (4)

(1) Istituto di Geofi sica Marina, Università di Pisa, Consorzio Universitario della Spezia, Italy
(2) Dipartimento di Scienze della Terra, Università di Pisa, Italy
(3) Dipartimento di Fisica and INFM, Università di Pisa, Italy
(4) Istituto Nazionale di Geofi sica e Vulcanologia, Roma, Italy

Abstract
The aim of this work is the formulation of a 3D model of the Mt. Amiata volcanic complex (Southern Tuscany) 
by means of geomagnetic data. This work is shown not only as a real test to check the validity of the inversion 
algorithm, but also to add information about the structure of the volcanic complex. First, we outline briefly the 
theory of geomagnetic data inversion and we introduce the approach adopted. Then we show the 3D model of the 
Amiata volcano built from the inversion, and we compare it with the available geological information. The most 
important consideration regards the surface distribution of the magnetization that is in good agreement with rock 
samples from this area. Moreover, the recovered model orientation recall the extension of the lava flows, and as a 
last proof of validity, the source appears to be contained inside of the topographic contour level. The credibility of 
the inversion procedure drives the interpretation even for the deepest part of the volcano. The geomagnetic signal 
appears suppressed at a depth of about 2 km, but the most striking consequence is that sub-vertical structures are 
found even in different positions from the conduits shown in the geologic sections. The results are thus in good 
agreement with the information obtained from other data, but showing features that had not been identified, stressing 
the informative power of the geomagnetic signal when a meaningful inversion algorithm is used.

Mailing address: Dr. Osvaldo Faggioni, Istituto di 
Geofisica Marina, Università di Pisa, Consorzio Universitario 
della Spezia, Via Vailunga 1, 19125 La Spezia, Italy; e-mail: 
of@castagna.it

Key  words   magnetic methods - Mt. Amiata volcano -
potential fi eld inversion  

1. Introduction

Geophysical data, and above all geomagnetic 
data, are particularly useful in volcanology to 
define the characteristics of a volcanic complex. 
A geomagnetic data set is very informative, in 

fact, if connected to magmatic rocks or lytotypes 
that show a particular intense value of the mag-
netic susceptibility.

Using adequate inversion software, one can 
find solutions that seem to correspond to the 
tectonic-structural model of the subsurface, 
but additional information can be obtained 
over areas that cannot be investigated directly. 
Practically, the geomagnetic data are used to find
solution about an equivalent source that should 
be responsible for the observed data, through the 
inversion process. The transfer from the observed 
data to a meaningful set of information on the 
generating source is not obvious, and has a fun-
damental relevance. This is particularly true for 
the geomagnetic field, that because of its di-



526

Osvaldo Faggioni, Nicolò Beverini, Fabio Caratori Tontini, Cosmo Carmisciano and Iacopo Nicolosi

polar nature is far from being interpretable «by 
eye».

It is well known moreover that any inversion 
process suffers from non-uniqueness problems. 
We know from Gauss’ theorem that when the 
magnetic field is known only on a bounding 
surface, there exists an infinite number of source 
distributions inside the volume that can generate 
this field. We call this a theoretical ambiguity. 
However, another kind of ambiguity has an 
algebraic origin: the number of available data 
is often under-sampled so that the description 
is not complete to fully describe the field. Many 
different source distributions can reproduce 

a particular discrete data set with the same 
degree of accuracy. In practice, it can easily be 
shown that any magnetic anomaly measured on 
the surface of Earth, might be reproduced by 
considering a superposition of (even negative) 
magnetic dipoles in a thin layer just beneath 
the surface. Today there are two principal 
strategies in order to develop an algorithm able 
to overcome these ambiguities. One possibility 
is given by parametric inversion. Knowing the 
anomalies generated by a simple causative body, 
it is possible to approximate the source finding
the «best one» (Bhattacharyya, 1980; Wang 
and Hansen, 1990; Zeyen and Pous, 1991). 

475
7

475
5

475
3

475
1

474
9

474
7

Fig.  1.  Topography of the Mt. Amiata complex (Gauss-Boaga projection).



527

A realistic inversion algorithm for magnetic anomaly data: the Mt. Amiata volcano test

Non-uniqueness is avoided by restricting the 
number of degrees of freedom to be fitted. In 
the second methodology, the Earth is divided into 
a large number of prismatic cells with constant 
magnetization inside and an algorithm minimizes 
some functional representing a suitable objective 
function of the model. For example, it is possible 
to avoid dispersion of the source by minimizing 
its total volume (Last and Kubik, 1983) or its 
momentum of inertia (Guillen and Menichetti, 
1984). Realistic models are obtained contrasting 
the depth decay of the kernel function with 
an appropriate weighting function (Li and 
Oldenburg, 1996) or introducing a multi-layer 
depth resolution in field measurements (Fedi 
and Rapolla, 1999). In this work, the result is 
achieved using an inversion scheme that has 
been developed by Caratori Tontini et al. (2003)
and in the following section an outline of this 
inversion scheme will be shown, to provide the 
formal context of the performed analysis. The 
data used for the inversion procedure come from 
the ENI-AGIP Division, and are used according 
to the scientific collaboration between ENI and 
the Istituto di Geofi sica Marina of La Spezia 
(Eni Explor. & Prod. Div. and IGMar, 2002). 
The geologic map and sections used for the 
interpretation come from the work by Enel 
«Direzione Studi e Ricerche, Centro di Ricerca 
Geotermica» and CNR «Istituto Internazionale 
per le Ricerche Geotermiche» (Calamai et al.,
1970; Gianelli et al., 1988).

Figure 1 shows the topographic contour lev-
el of the Mt. Amiata complex projected onto a 
Gauss-Boaga reference system. The Mt. Amiata
shows two major peaks, La Vetta (1735 m), 
and La Montagnola (1571 m) aligned along 
a WSW-ENE direction. It is a moderate size 
silicic volcanic complex, whose main activity 
had two principal phases at about 300 000 and 
200 000 years ago (Ferrari et al., 1996). The first
period is characterized by the emplacement of a 
Trachi-Dacitic Basal complex (BTC), made of 
two separate sub-units (fig. 3). The whole BTC 
complex lies over a 90 km2 area with an average 
thickness of about 150-200 m, and probably it 
is the result of a light explosive activity. The 
second phase happened after 100 000 years and 
its main products were domes and lavic flows
with composition variable from Trachi-Dacitic, 

Trachitic and Latitic (DLC). These domes and 
flows, where visible, are aligned along a WSW-
ENE direction as the BTC complex. At the end 
of the eruptive epoch, two smaller Olivine-Latitic 
Lava flows (OLL) were emitted.

The detection of fault systems and their 
origin in this area is difficult because of the 
vast erosional cover surrounding the domes and 
flows and for the dense vegetation. However 
the Mt. Amiata is oriented WSW-ENE and two 
faults, with a length of about 2.5 km, seems to 
be the origin of the BTC collocation. A certain 
number of other smaller faults were activated 
during the second period of activity (Marinelli 
et al., 1993). 

2.  Outline of the inversion algorithm

In this section, we show briefly the method 
used to perform the inversion, its constraints 
and the way it works. A full treatment of the 
topic can be found in Caratori Tontini et al.
(2003), together with some tests, based on both 
synthetic and real data that gives reliability to 
the method. 

Here we report the formalism and the basic 
information about the initialization and the 
utilization of the algorithm, to fully understand 
the inversion of the Mt. Amiata geomagnetic 
data. Let us suppose that we have partitioned 
the data set into a 2D grid that we call d (i, j)
(observations). We want to interpret this data 
set in terms of the magnetization of the generat-
ing source. We adopt a mapping of the region 
presumably containing the source, dividing it 
into a certain number (n

x
, n

y
, n

z
) of prismatic 

cells with unitary magnetization. Obviously, 
the magnetic anomaly field generated by a 
particular subsurface configuration is obtained 
multiplying the unitary cell contribution for the 
magnetization of the cell, and summing over the 
whole number of cells

      
          (2.1)

where DF(i, j ) is the grid of the predicted data 
and M(l, m, n) is the cell magnetization. The 

∆ ∆F i j F i j l m n M l m n
l m n

n n nx y z

, ˜ , , , , , ,
, ,

, ,

( ) = ( ) ( )∑



528

Osvaldo Faggioni, Nicolò Beverini, Fabio Caratori Tontini, Cosmo Carmisciano and Iacopo Nicolosi

analytic expression of the contribution at one 
cell ∆ ˜ , , , ,F i j l m n( ) is well-known and here is 
not reported for conciseness, but can be found 
in Bhattacharyya (1964); Rao and Babu (1991). 
The inversion procedure works minimizing 
the difference between the observed data set
d (i, j ) and the prediction grid DF(i, j ) in the least 
squares sense, provided that some constraints 
over the magnetization are imposed, otherwise 
it is well-known that the problem has multiple 
solutions.

The algorithm adopts a smoothness constraint 
and the bound of positivity imposed by using a 
Gaussian approximation. Practically the source 
is expanded using a predetermined number 
of 3D Gaussian functions that are positively 
constrained. This particular choice introduces 
a non-linear relationship among the parameters 
defining the source, but has the fundamental 
relevance of drastically reducing the degrees of 
freedom of the problem, permitting however the 
reconstruction of the most articulated sources. 
The smoothness constraint moreover is imposed 
naturally in this way. Within this choice, the 
magnetization is parameterized as

      
      (2.2)

where the set of 7 parameters (A
k
, x

k
, y

k
, z

k
, sx

k
, sy

k
,

sz
k
) define completely the k-th Gaussian function, 

while the number n
g
of functions used as the basis 

of the envelope is chosen by the user according 
to some empirical considerations. If the algorithm 
starts with some unnecessary function, i.e. n

g
is

redundant, the amplitude of these superfluous 
functions is compelled to a null value through a 
process of annihilation that is explained in detail 
by Caratori Tontini et al. (2003). 

It is a valid geological observation that of-
ten the spatial variations of physical properties 
are smooth. This is particularly true for some 
geological scenarios: for example smooth mag-
netization variations can be seen near magmatic 
intrusions, and smooth density variations may 
apply to sedimentary formations under different 

level of compaction. The positivity constraint, 
that is of fundamental relevance to reduce the 
ambiguity domain, in the case of geomagnetic 
data is obvious because the paramagnetic effects 
of matter are usually stronger than the diamagnetic 
ones. This further limitation is imposed through 
the use of a positivity mapping function for the 
amplitude parameters A

k
(Oldenburg and Li, 1994; 

Li and Oldenburg, 1996). The algorithm proceeds 
by means of a modified Levenberg-Marquardt 
iteration scheme for non-linear least squares 
minimization to determine the best-fit source, 
together with the statistical confidence level for 
the parameters. Depending on the number n

g
of

functions involved, even the most composite 
models can be reconstructed by the inversion 
algorithm to achieve a fine resolution. 

3.  The Mt. Amiata aeromagnetic 
     data inversion

The data used for the inversion were col-
lected during the survey performed by AGIP in 
1978-1979 in a large area, including Tuscany 
and the Tyrrhenian sea, using a CFS Cesium 
magnetometer. The upper part of fig. 2 shows 
the magnetic anomaly using Gauss-Boaga 
kilometric coordinates reference system. The 
total field data (time corrected) were levelled 
and filtered through standard procedures, and 
then a polynomial regional field (order 2) was 
residuated to obtain the magnetic anomaly. 
The survey in this area was made through lines 
(direction SW-NE) with an average spacing 
of 2 km, orthogonally intersected by tie lines 
(direction NW-SE) with an average spacing of 
5 km. The sampling pass along each profile was 
about 500 m, at an altitude of 1600 m.

The data were gridded through a minimum 
curvature method with a cell size of 750 m, for 
a spectral resolution of 1.5 km. The magnetic 
anomaly is very articulated, showing different 
positive local maxima with the associated 
negative lobes, suggesting the idea of a very 
articulated source for geometry and depth. For 
these reasons, these 22 ¥ 16 data are inverted 
using a prismatic region defined by the east 
interval (1708; 1716) km and north (4747; 4755) 
km with 4 km depth, divided into 6912 cubic 

M l m n Ak
k

ng

, ,( ) ≡ ⋅
=

∑
1

x l x

x

y m y

y

z n z

z
k

k

k

k

k

k

exp⋅ −
( ) −( )

−
( ) −( )

−
( ) −( )











2

2

2

2

2

2σ σ σ   



529

A realistic inversion algorithm for magnetic anomaly data: the Mt. Amiata volcano test

Fig.  2. Magnetic anomaly and recovered model compared with the topographic contour level (Gauss-Boaga pro-
jection). The broken lines represent the geologic sections of fig. 4.



530

Osvaldo Faggioni, Nicolò Beverini, Fabio Caratori Tontini, Cosmo Carmisciano and Iacopo Nicolosi

cells (24 ¥ 24 ¥ 12). The starting condition for the 
algorithm employed 30 Gaussian functions.

The lower part of fig. 2 shows the recovered 
model plotted by means of horizontal cross-
sections. The Amiata topographic contour level 
and the trace of two interpretative geological 
sections are superimposed on the model (fig. 
4). Apart from very small magnetization echoes 
of the deepest source in the first cross section, 
due to the smoothness constraint, the model 

appears to be fully contained inside the Mt. 
Amiata topography. The model has highlighted 
a shallow distribution of sources with a thick-
ness of about 2000 m in the central area, decreas-
ing towards the lateral margins. The overlap of 
known dome locations with the inversion model 
gives a key to understand the geological meaning 
of the model itself; there is a good correlation 
between the surface distribution of domes 
and the recovered model inside the Amiata 

Fig.  3. Surface distribution of the recovered source compared with the geologic map of the Mt. Amiata area and 
the geologic sections (Gauss-Boaga projection).



531

A realistic inversion algorithm for magnetic anomaly data: the Mt. Amiata volcano test

volcanic edifice. We suppose that the highest 
magnetized recovered bodies belong to the DLC 
and OLL volcanic complexes. Two interpretative 
geological sections (Calamai et al., 1970; Giannelli 
et al., 1988) show two main conduits located in 
proximity of «La Vetta» and «La Montagnola» that 
represent the locations of the shallower portion of 
magma ascent during the emplacement of domes 
structures. Probably those vertical structures reach 
a depth of 5-7 km, where a magmatic intrusive 
granitic body (Giannelli et al.,1997) that supplied 
the dome pile up is supposed to be located. A 
magnetic signature is given only by the upper 
portion of those vertical structures, because of 
the very shallow Curie isotherm of the Amiata 
geothermal region (Baldi et al., 1995).

In fig. 3 the recovered model has been spread 
over the topographic surface for comparison 
with the rock magnetization data sampled 
during field measurements that the Istituto di 
Geofisica Marina performed in the area of 
the Mt. Amiata, using a GMS-2 susceptibility 
meter. The magnetic susceptibility of different 
lytotypes coming from rock samples of BTC, 
DLC and OLL was measured, and an average 
magnetization was calculated from the different 
samples to avoid statistical errors coming from 
geometrical irregularities of the sample surface. 
The first three horizontal cross-sections of the 

recovered model have been fused into a unique 
map, in order to overlap the data found during the 
inversion procedure on the topographic surface of 
Mt. Amiata. The high magnetic behaviour of the 
rocks coming from DLC and OLL, with respect 
to the lowly magnetized complex of BTC, is 
confirmed by the recovered model. The model 
shows the presence of the generating source 
in the central part of the area as arguable from 
the geologic map. The source geometry appears 
aligned along the WSW-ENE direction in good 
agreement with the orientation of the principal 
fractures that caused the emplacement of the 
volcanic complex; moreover the magnetization 
peaks seems to confirm the presence of localized 
sources that should be referred to the volcanic 
conduits system mentioned before. The inversion 
has highlighted that the magnetization of sub-
vertical sources located inside Amiata volcanic 
edifice is stronger than that measured on the 
surface; the deepest part of the domes that have 
a surface topography expression like «La Vetta» 
and «La Montagnola», show a higher degree of 
magnetization before it reaches the shallow Curie 
isotherm: this is a new fundamental constraint to 
be considered to understand the petrographic 
evolution of the Amiata volcanic system, im-
posed only by the recovered inversion model 
from magnetic anomaly data.

Fig.  4.  Geologic sections of the area of the Mt. Amiata.



532

Osvaldo Faggioni, Nicolò Beverini, Fabio Caratori Tontini, Cosmo Carmisciano and Iacopo Nicolosi

4.  Conclusions

From the data obtained by ENI-AGIP Di-
vision we have evaluated the magnetic anomaly 
of the Mt. Amiata volcanic complex. From the 
inversion of the extracted data set we have shown 
a 3D model of the magnetic source inside the 
apparatus. The model shows the geometry of the 
magnetic sources of the volcanic edifice from the 
altitude of 1.5 km to the depth of 2.2 km, where the 
geomagnetic signal loses its informative capability. 
The recovered model is in good agreement with the 
information coming from the geologic knowledge 
and the susceptibility measurements of the area 
of interest, showing however characteristics and 
features that were not still found. In particular, we 
were able to suppose the presence of sub vertical 
structures that should be connected to intrusions 
or localized magma ascent conduits characterized 
by a magnetization greater than the surface portion 
one. The surface distribution of the magnetization 
is in good agreement with the geologic map and 
the rock samples measurements. This study is 
thus fundamental in the definition of the geologic 
submerged structures of the Mt. Amiata apparatus, 
otherwise not accessible by direct methods.

Acknowledgements

We thank ENI-AGIP Division for permission 
to use the Amiata geomagnetic data. We are 
obliged to Angelo De Santis for his helpful and 
competent review. We are also grateful to Paolo 
Stefanelli (IGMar) for his help in measurements 
of Amiata rock samples susceptibility.

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