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THE COMMON EVOLUTION OF GEOMETRY AND ARCHITECTURE FROM A GEODETIC POINT OF VIEW / Bellone,
Tamara; Fiermonte, Francesco; Mussio, Luigi. - In: INTERNATIONAL ARCHIVES OF THE PHOTOGRAMMETRY,
REMOTE SENSING AND SPATIAL INFORMATION SCIENCES. - ISSN 2194-9034. - ELETTRONICO. - XLII-
5/W1(2017), pp. 623-630. ((Intervento presentato al convegno GEORES 2017 International Congress - Geomatica e
conservazione tenutosi a Florence, Italy nel 22 – 24 May 2017.

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THE COMMON EVOLUTION OF GEOMETRY AND ARCHITECTURE FROM A GEODETIC POINT OF
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International Society for Photogrammetry and Remote Sensing



THE COMMON EVOLUTION OF GEOMETRY AND ARCHITECTURE FROM A 

GEODETIC POINT OF VIEW 

Tamara Bellone*. Francesco Fiermonte**, Luigi Mussio*** 

*DIATI, Politecnico di Torino, Turin, Italy

**D.IST, POlitecnico di Torino, Turin, Italy

***DICA, Politecnico di Milano, Milan, Italy

KEYWORDS: Architecture, Euclidean and non-Euclidean Geometries, Projective Geometry 

ABSTRACT: 

Throughout history the link between geometry and architecture has been strong and while architects have used mathematics to 

construct their buildings, geometry has always been the essential tool allowing them to choose spatial shapes which are aesthetically 

appropriate. Sometimes it is geometry which drives architectural choices, but at other times it is architectural innovation which 

facilitates the emergence of new ideas in geometry. 

Among the best known types of geometry (Euclidean, projective, analytical, Topology, descriptive, fractal,…) those most frequently 

employed in architectural design are: 

 Euclidean Geometry

 Projective Geometry

 The non-Euclidean geometries.

Entire  architectural periods are linked  to specific types of geometry. 

Euclidean geometry, for example, was the basis for architectural styles from Antiquity through to the Romanesque period. 

Perspective and Projective geometry, for their part, were important from the Gothic period through the Renaissance and into the 

Baroque and Neo-classical eras, while non-Euclidean geometries characterize modern architecture. 

1. INTRODUCTION

For centuries geometry was effectively Euclidean Geometry: it 

was thought to be the one real geometry, representing space in a 

realistic way and, thus, no other geometry  was believed 

possible. (Stewart, 2016). 

When global navigation began, the natural, roughly spherical 

geometry of the earth's surface was revealed (Stewart, 2016). 

On a sphere, geodesics will necessarily meet: in this geometry 

parallel lines are absent. 

However, hyperbolic geometry was developed (in the 19
th 

century) before elliptic geometry, and in the former there are 

infinite lines parallel to a given line at a given point. 

Today there are a variety of non-Euclidean geometries, 

corresponding to curved surfaces. The general theory of 

relativity demonstrated that in the vicinity of bodies of great 

mass such as stars, space-time is not flat but, rather, curved. 

There is another type of geometry, called projective geometry, 

the development of which was based the perspective techniques 

used by painters and architects. If we are on a Euclidean plane 

between two parallel lines, we see that these meet on the 

horizon: the horizon is not part of the plane but is a "line at 

infinity". 

Sometimes it is geometry which drives architectural choices, 

but at other times it is architectural innovation which facilitates 

the emergence of new ideas in geometry: in any case, 

throughout history the link between geometry and architecture 

has been strong.

Entire architectural periods are linked to specific types of 

geometry. Euclidean geometry is the basis for architectural 

styles from Antiquity through to the Romanesque period. 

Perspective and Projective geometry, for their part, were 

important from the Gothic period through the Renaissance and 

into the Baroque and Neo-classical eras, while non-Euclidean 

geometries characterize modern architecture. 

2. FROM ANTIQUITY TO RENAISSANCE

From Antiquity through to the Renaissance, architects defined 

the proportions and the symmetry of their buildings, and the 

relationship with the environment by means of geometrical 

solutions. 

Flooding of the Nile symbolized the annual return of chaos, 

geometry, used to restore the boundaries, was perhaps seen as 

restoring order on earth: geometry acquired a kind of 

sacredness. 

A golden ratio pyramid is based on a triangle whose three sides 

represent the mathematical relationship that defines the golden 

ratio. This triangle is known as a Kepler triangle, where φ is 

1.618590347 (Fig. 1). 

Fig. 1 The Kepler triangle 

The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-5/W1, 2017 
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https://en.wikipedia.org/wiki/Kepler_triangle


Recall that we denote by φ (in honor of Fidia) the golden 

number. If a segment AB is divided into two parts, such as : 

AB:AC=AC:CB 

the point C divides the segment in the so called golden ratio. 

The number AB/AC is the golden number. In the case AB was 

equal to 1, φ is 1.618590347. Indeed: 

𝑥

1
=

1

𝑥 − 1
 (1) 

𝑥 =
1 + √5

2
≅ 1.618 

Leonardo Pisano, Fibonacci (1170-1250), discovers a series of 

particular numbers: the first two terms of the sequence are 1 and 

1. All other terms are the sum of the two terms which precede

them.

A remarkable feature of these numbers is that the relationship

between any Fibonacci number and the one immediately

preceding it tends to φ as n tends to infinity.

“ Do the wonderful arrangement of the petals of a rose, the

harmonious cycle of certain shells, the breeding of rabbits and

Fibonacci's sequence have something in common?.. Behind

these very disparate realities there always hides the same

irrational number commonly indicated by the Greek letter φ

(phi) . A proportion discovered by the Pythagoreans, calculated

by Euclid and called by Luca Pacioli divina proportione”

(Mario Livio, The Golden Section) .
A logarithmic spiral where the constant relationship between the 

consecutive beams is equal to φ is called”golden” (Fig.2). 

Fig.2 The golden spiral 

While some scholars assert that aesthetics did not exist in 

Ancient Greece, it is well known that the Greeks' architectural 

works adhered to well-defined standards. 

Art was any object whose creation derived from the technical 

skills or expertise of a craftsman and which recreated an order 

evoking the order of nature (Koσμος).  

The dimensions of an object of beauty are determined by the 

relationships between its component parts. The golden ratio was 

introduced by the Pythagoreans as the ratio between the 

diagonal and the side of the regular pentagon. 

The symbol of the pentagonal star was the sign of the 

Pythagoreans, for whom it represented love and beauty, health 

and balance (Corbalan, 2010). 

Temples represent the quintessence of Greek architecture, and 

Euclidean geometry was the canon defining the proportions of 

the component parts of these buildings. Harmonic ratios derived 

from the study of this type of geometry, in turn, linked to 

musical intervals musical intervals. Thus, Greek architecture 

considers ratios to be bound up with Mathematics, Philosophy 

and Music. 

This tradition is based upon the idea expounded by Pythagoras 

and by Plato that numerical proportions and symmetries are the 

pillars holding up the world. 

Greek architects also used the sectio aurea (the golden ratio) 

since proportions could not be free, but  had, rather, to align 

with the cosmic order. Golden rectangles are observable on the 

façade of the Parthenon (Fig. 3). In Parthenon the overall height 

is the golden section of the width of the front part; then the 

facade has the size of a golden rectangle. This golden ratio is 

repeated several times between different elements of the front, 

for example, between the overall height and the height of which 

is located the entablature. 

Fig. 3 The Parthenon (Athens, V century b.C.) 

In any case, the argument that the architecture of the famous 

monument was based on the golden section appears unprovable, 

as it is, moreover, for all the buildings of antiquity. 

It might indeed appear that constructions designed using the 

golden ratio are based on an innate human sense of the 

aesthetic: Puerta del Sol near La Paz, for example, is based on 

golden rectangles (Fig. 4) 

Fig.4 Puerta del Sol (Tiahunaco, uncertain age) 

Thales calculated the height of the Great Pyramid of Cheops, 

demonstrating that the real height of the pyramid and his pole 

were in equal proportion to their shadows: this is, at one and the 

same time, a classical indirect measurement and a basic theorem 

of Euclidean geometry. 

Harmony engendered by proportions and symmetry is also 

observed and celebrated in Vitruvius’s “De Architectura”. 

Vitruvius describes the three limits of architecture: firmitas, 

utilitas, venustas (solidity, utility, beauty respectively. Geometry 

The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-5/W1, 2017 
GEOMATICS & RESTORATION – Conservation of Cultural Heritage in the Digital Era, 22–24 May 2017, Florence, Italy

This contribution has been peer-reviewed.   
doi:10.5194/isprs-archives-XLII-5-W1-623-2017 624



 

is involved both in visible and structural characters (venustas 

and firmitas) 

 

 
 

Fig. 5 The Great Pyramid of Cheops (2550 b.C.) 

 

 

Geometry is involved both in visible and structural characters 

(venustas and firmitas) 

Euclidean geometry informed architectural styles up to the 

Romanesque period. Sectio aurea was of great interest during 

the Renaissance, from Leonardo da Vinci to Leon Battista 

Alberti: one charming example of such is the Malatestian 

Temple at Rimini (L.B. Alberti, 1450-1468) (Fig.6). 

 

 
 

Fig. 6 The Malatestian Temple (Rimini, 1503) 

 

 

The Holy Family by Michelangelo is organized according to the 

pentagonal star (Fig. 7). 

Basic thought of Pythagoreans is that the number is substance 

of reality: mathematical measurement (μετρου) is adequate for 

comprehension of the order in the world.  

For Pythagoras, numbers exist in the space: so, no contradiction 

takes palec between mathematics and geometry. 

Also, at the end of Plato’s research, the science of metrology is 

formalized as the key of knowledge. This is worth even for man 

and his behaviour, also related to intercourse with other men 

and with his own activity, both mental and social. 

 

 
 

Fig. 7 The Holy Family (Michelangelo, 1506-1508) 

 

 

3. PERSPECTIVE AND PROJECTIVE GEOMETRY 

As early as 1435, Alberti wrote the first book about the new 

technique of perspective, the “De Pictura”. If some scholars 

assert that this principle  is quite obvious, since the retinal 

image is in perspective, it is a different matter when discussing 

vision: Phidias made statues which, in order to be coherently 

proportioned atop a column, had to be altered in form. Columns 

closer to the observer seem narrower than those further away, 

and one famous correction of perspective is to be seen in the 

inward-slanting columns of the Parthenon. 

It is interesting to compare two paintings depicting the 

Annunciation, with (Fig.9) and without (Fig.8) the use of 

perspective. 

 

 
 

Fig. 8 Annunciation (Andrej Rublev, 1410) 

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Fig. 9 Annunciation (Leonardo da Vinci, 1472-1475) 

 

 

In this context, the way to acquire a correct perspective is 

shown by a comparison between a flat byzantine representation 

(Fig. 10) and an attempt to draw the perspective in Gothic 

pictures (Fig. 11). 

 

 
 

Fig. 10 The port of Classis (Sant’Apollinare nuovo, Ravenna, 

VI century) 

 

 

 
 

Fig. Joachim and Anne’s meeting (Giotto, Scrovegni Chapel, 

Padua, 1303-1305) 

 

Euclid's optics had already determined that objects create a cone 

of rays converging in the observer's pupil. Perspective was 

concerned with the intersection of cone and plane of  

representation 

 Perspective conceives of the world from the viewpoint of a 

“seeing eye”, that is an individual who is free to represent the 

world beyond mere religious dogmas: the relationship between 

individualism and perspective is an important one. The painting 

The ideal city (Fig. 12), is a precise central projection. The 

author is unknown, possibly of 15 
th

 century.
1
  

                                                                 
1
 Some scholars think of Leon Battista Alberti as the 

author of the painting. 

The only vanishing point is at the portal of the temple 

 

 
Fig. 12 The ideal city (Anonymous, 1490) 

 

 

In architecture, a solid perspective gives the beholder the 

illusion of a greater depth than is real. One clear example is the 

apse of Saint Mary by Saint Satyrus Church in Milan by 

Bramante (Fig. 13).  

Although the artist had at his disposal a depth of only 97 cm, he 

gave the building a monumental impact through the optical 

illusion provided by an apparent barrel vault. 
 

 
 

Fig. 13 Saint Satyrus Church (Milan, 1482) 

 

 

Perspective was a Renaissance invention, but the basic idea of 

projection is much older and stemmed from the need to 

represent the Earth on a plane. Both the Greeks (Hipparchus, 

Ptolemy) and the Persians (Al Biruni, the astronomer and 

mathematician who discovered the Earth's radius by indirect 

measurements, different from those of Eratosthenes, whose 

work was, nonetheless, known to him), were able to project the 

globe on a plane and to detect single points using coordinates 

(latitude and longitude). The Arabs indeed imported into Europe 

Indian, Arabic, and Persian ideas, not to mention ones from the 

Greek tradition, in the fields of Mathematics, Cartography and 

Geography,. 

Ptolemy’s world map is a polar stereographic conformal 

projection which was in use until explorations from Marco Polo 

through to Columbus led first to its modification, and later to its 

abandonment (Mercator, 1569). 

Generally, architects and painters of the 16
th

 century used, 

particularly for ceiling frescos, a series of vanishing points in 

order to limit the paradoxical effects of perspective. Some 

innovators, such as Niceron, Maignan and Andrea del Pozzo, 

used a unique, central viewpoint which resulted in significant 

distortion at the edges.  

In the convent of Trinità dei Monti, images of saints which are 

clearly visible from a precise, lateral viewpoint (Fig.14.), 

dissolve as one comes closer to the center of painting (Fig.15).  

In 1632, Niceron wrote “De perspectiva curiosa”, a treatise on 

Anamorphosis. 

 

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Fig.14 St. Francis from Paola -  normal view (Maignan, Trinità 

dei Monti Rome, 1642) 

 

 
 

Fig. St. Francis from Paola -  anamorphic  view (Maignan, 

Trinità dei Monti Rome, 1642) 

 

The invention of perspective, together with cartographic and 

anamorphic experimentation, also inspired Projective Geometry. 

Desargues, a Lyonnais painter, architect and mathematician, 

broadens perspective, increasing the use of vanishing points 

(points at infinity). He believed that a geometrical entity could 

be distorted continuously: when one moves one of the foci of an 

ellipse to infinity, a parabola is obtained.  

Subsequently, Baroque architecture would express ideas of 

infinite time and space, in step with the philosophical views of 

Giordano Bruno. 

According to Desargues: 

 two points identify one and only one straight line 
 two straight identify one and only one point 

The consequence is that there are no parallel lines and the 

conical are indistinguishable. (Odifreddi, 2011). 

Projective geometry is concerned with the study of the 

properties of  figures, with respect to a series of transformations, 

defined as projective, obtained by operations of projection and 

section that can alter the metric properties, but not the projective 

ones  

The Baroque is constantly in search of free and open surfaces, 

elliptical and in constant transformation. Guarini, in the Chapel 

of the Holy Shroud (end of XVII century) creates optical  

effects and continuous geometric transformations (Fig.16); in 

the San Lorenzo Church (also in Turin), he brings together 

convex and concave surfaces (Fig. 17).  

During his stay in Paris, Guarini studied infinitesimal calculus 

and the theories of Desargues; many scholars suppose that in the 

domes of Guarini projective geometry is a theoretical basis. 

 

 

 
Fig. 16 Chapel of the Holy Shroud (Guarini, Turin, 1694) 

 

 
 

Fig. 17 San Lorenzo Church (Guarini, Turin, 1668-1687) 

 

Borromini shapes undulating architraves, skewed arches and 

oblique forms (Fig. 18). 

 

 
 

Fig. 18 Sant’Ivo alla Sapienza (Borromini, Rome 1642-62) 

 

The colonnade of Piazza San Pietro (by Bernini), which is 

straight to the eye of the observer at the center of the piazza, 

appears continuously transformed as the closer up he comes  

with the  columns seemingly oblique (Fig. 19) 

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Fig. 19 View of St. Peter’s square (Piranesi, 1748) 

 

Since the advent of Computer Vision a few decades ago, 

projective geometry has been arousing renewed interest. In fact, 

any understanding of how images are formed depends on an 

analysis of the process by which a (three-dimensional) scene is 

projected onto a (two-dimensional) plane. 

In a very concise terms, the process can be divided into two 

distinct parts, one being essentially geometric and while the 

other radiometric ): 

 the determination of the image point position; 
 the determination of the resulting image point 

brightness. 

Thus, the first phase itself of the process is dependent on 

concepts and methods of projective geometry. In particular, 

projective transformations of the plane shape the geometric 

distortions, which are present when an object is represented in a 

flat image (captured by a sensor, such as a digital camera, 

however arranged in 3D space). 

Some properties of the object, then, are retained in the passage 

from object to image (such as collinearity), while others are not 

(for example, parallelism is not preserved, at least not 

generally). Therefore, projective geometry models image 

formation and favours its mathematical representation, adapted 

to the calculation, i.e. by introducing algebra into geometry, to 

describe geometric entities in terms of coordinates and other 

algebraic entities. 

 

4. NON-EUCLIDEAN GEOMETRIES  

Perception of parallelism is shaky, perhaps a cultural issue, 

while perspective vision is perhaps a symbolic form (Panofsky): 

the time is ripe to abandon the Euclidean space in science and 

the arts.  

It is interesting to compare the paintings of Van Gogh or 

Cézanne that represent what the artists see, with perspective 

drawings of the same scene: the effect is of alienation. (Fig. 20). 

The curve perception of straight lines depends on the 

physiology of the eye: the retina is curved. Our eye knows all 

three geometries Euclidean, spherical and hyperbolic 

(Odifreddi, 2011). 

Topographic work for the Duchy of Hanover caused Gauss to 

deal with geodetic triangles and theoretical Geodesy, and thus to 

anticipate hyperbolic and elliptical geometries (Lobačevsky and 

Riemann). 

It is easy to see that all triangles upon a sphere (i.e. the Earth, 

more or less...) have angles whose global amplitude is over 

180°. Also, all geodesics meet at two points only. In this case 

we can say that curvature is positive. Moreover, in the said 

geometry, parallels are quite absent. 

 

 
 

Fig.20 Le café de nuit (Van Gogh, 1888) 

 

On the contrary, for hyperbolic geometry, total amplitude of 

inner angles for triangles is less than 180° and the curvature is 

said negative: in this case, the number of parallels at a single 

point to a given geodesic is unlimited.  

Above a spherical surface, when a triangle is enlarged, also the 

width of inner angles increase (positive curvature); the opposite 

happens on hyperbolic surfaces (negative curvature). On a flat 

surface the amplitude doesn’t change. (O’Shea, 2007). 

The Earth continues to appear flat in restricted areas, i.e. the 

sphere can appear, in small scale, Euclidean (Fig. 21) 

 

 
 

Fig. 21 The Montréal Biosphère (Fueller,1967) 

 

A forewarning of later artistic revolutions was the dissolution of 

classical geometric forms led by the Macchiaioli and the early 

Impressionists (Fig. 22 and Fig. 23) . 

 

 
 

Fig. 22 Il caffé Michelangiolo (Ceccioni, 1867) 

The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-5/W1, 2017 
GEOMATICS & RESTORATION – Conservation of Cultural Heritage in the Digital Era, 22–24 May 2017, Florence, Italy

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https://en.wikipedia.org/wiki/Montr%C3%A9al_Biosph%C3%A8re


 

 
 

Fig. 23 The red jacket (Zandomenghi, 1895) 

 

Both non-Euclidean Geometry and the Theory of Relativity are 

at the basis of Cubism. Cubist painting introduces a fourth 

dimension: time; in point of fact, one picture can have 

simultaneously different viewpoints, permitting analysis at 

different times (Fig. 18). 

 

 
 

Fig. 24 Portait of Dora Maar (Picasso, 1937) 

 

The idea of watching an object from all viewpoints has to do 

with going beyond the third dimension, Objects are broken and 

re-assembled as well as being displayed in a broader context. 

Non-Euclidean geometries are present in the work of artists like 

Picasso and Malevich (Fig. 19), and in architectural 

Constructivism and Deconstructivism. 

The theory of relativity concludes that the three geometries 

Euclidean, hyperbolic and elliptic can be successfully apply in 

different areas.  

 

 
 

Fig. 25 The Woodcutter (Malevich, 1912) 

 

Shukhov, architect, engineer and mathematician, devised, like 

Gaudi (Fig.26) double-curvature structures, hyperboloids of 

revolution, based on non-Euclidean geometry.  

 

 

 
 

Fig. 26 Casa Milà (Barcelona, 1906-12) 

 

 

The hyperboloid tower (Fig. 27) built by Shukhov for the 

Nizhny Novgorod Exhibition (1896) was the prototype for 

many industrial buildings, and perhaps it was thanks to this that 

he had some influence on  Russian Constructivism. Indeed, 

Constructivism encouraged the use of industrial materials and of 

shapes derived from technical processes. 

 

 
 

Fig.27 The Shukhov Tower (1920-1922) 

 

 

Constructivism created buildings and monuments which broke 

the rules of compositional unity. Vladimir Tatlin, artist and 

architect, projected a Tower in honor of the Third International, 

that was never built (Fig 28). In a period of reaction , Soviet 

architecture returned to Neo-classicism. 

In the nineteen-eighties, some architects declared themselves 

Deconstructivists, in reference to Derrida and 

Deconstructionism, on the one hand, and, on the other, to 

Russian Constructivism - destroyer of Euclidean geometry 

based upon harmony and proportion - which they sought to 

infuriate and supplant. 

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GEOMATICS & RESTORATION – Conservation of Cultural Heritage in the Digital Era, 22–24 May 2017, Florence, Italy

This contribution has been peer-reviewed.   
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Fig 28 Tower of Third International (Petrograd, 1919-20) 

Walls of buildings slope and open out, and the buildings 

themselves are out of place in their locations: cuts, 

fragmentations and asymmetry are their main characteristics. 

One important representation is the Guggenheim Museum in 

Bilbao, by Frank Gehry (1997) (Fig. 29). 

Fig.29 Guggenheim Museum (Bilbao, 1997) 

Frank Owen Gehry and Le Corbusier are two symbols in 

modern architecture. Le Corbusier, in his times, is impressed by 

the cubistic rationalism (he was a personal friend of some of 

most important painters of this art movement). 

The golden number entered in the architecture of Le Corbusier, 

as in the Villa Savoye (Fig 30.), or in La Ville radieuse in 

Marseille, although in the course of times a noticeable evolution 

is to be seen in his many works (Zeri, 1994) (Fig.31 ) 

Frank O.Gehry is an eclectic personality; a special feature in his 

work is avoiding forms and shapes of Euclidean geometry and 

perspective, with special preference for what  appears as 

disharmonic and asymmetric (Zeri, 1994) (Fig. 32). 

Fig. 30 Villa Savoye (Poissy, 1928-31) 

Fig. 31 Chapelle Notre dame du Haut (Ronchamp,1950) 

Fig. 32 Dancing House (Prague, 1996 ) 

REFERENCES 

Corbalan, F., 2015. La sezione aurea. RBA, Milano 

Livio, M., 2006. La sezione aurea. Mondadori, Milano 

Odifreddi, P., 2011. Una via di fuga. Mondadori, Milano 

O’Shea, D., 2007. La congettura di Poincaré. Rizzoli, Milano. 

Stewart, I., 2016. Numeri incredibili, Bollati Boringhieri, 

Torino 

Urgelles, J.G., 2015. Quando le rette diventano curve. RBA, 

Milano 

Zevi, B., 1994. Architettura della modernità. Newton Compton, 

Roma 

The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-5/W1, 2017 
GEOMATICS & RESTORATION – Conservation of Cultural Heritage in the Digital Era, 22–24 May 2017, Florence, Italy

This contribution has been peer-reviewed.   
doi:10.5194/isprs-archives-XLII-5-W1-623-2017 630