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Journal of the Korean Astronomical Society - Vol. 52 , No. 5

[ Article ]
Journal of the Korean Astronomical Society - Vol. 52, No. 4, pp.99-108
Abbreviation: JKAS
ISSN: 1225-4614 (Print) 2288-890X (Online)
Print publication date 31 Aug 2019
Received 04 May 2019 Accepted 11 Jun 2019
DOI: https://doi.org/10.5303/JKAS.2019.52.4.99

THE EVOLUTION OF ASTRONOMICAL OBSERVATORY DESIGN
MIGUEL ÁNGEL CASTRO TIRADO1, 2 ; ALBERTO J. CASTRO-TIRADO1, 2
1Instituto de Astrofísica de Andalucía (IAA-CSIC), Glorieta de la Astronomía s/n, 18008 Granada, Spain (macastrotirado@gmail.com)
2Unidad Asociada al CSIC Departamento de Ingeniería de Sistemas y Automática, Escuela de Ingeniería Industrial, Universidad de Málaga, Arquitecto Francisco Peñalosa, 29071 Málaga, Spain (ajct@iaa.es)

Correspondence to : M. A. Castro-Tirado


Published under Creative Commons license CC BY-SA 4.0
Funding Information ▼

Abstract

This work addresses the development of the astronomical observatory all through history, from an architectural point of view, as a building in relation to the observing instruments and their functioning as a heterogeneous work center. We focused on 32 observatories (in the period 1259-2007) and carefully analyzed the architectures. Considering the impact of the construction itself or its facilities on the results of the research (thermal or structural stability, poor weather protection, turbulence, etc.), there is little attention paid to theories or studies of the architectural or construction aspects of the observatories. Therefore, this work aims to present a theoretical-critical contribution that, at least, invites the reflection of those involved in the development of astronomical observatories in the future.


Keywords: history and philosophy of astronomy, telescopes

1. INTRODUCTION

The theoretical approach to astronomical observatories has its origin in the roots of the modern observatory (Brahe 1602; Caramuel de Lobkowitz 1678). However, historical-descriptive works that consider a particular project are the most common during the next centuries. In addition, some studies appeared focused on specific periods (Sayili 1960; Kwan 2012; Leverington 2017), others with a more general retrospective nature (Donnelly 1971; Krisciunas 1999; Wolfschmidt 2008) and only a few works focused on the architectural-constructive aspects of the observatories (Dumitrache & Dumitrache 2009; Waumans 2013).

The concept of astronomical observatory itself lacks a precise and globally accepted definition given that historically there has not been a critical-intellectual movement that theorized about its nature or conception. Although it may seem obvious, what is understood by an observatory has changed over the years, and, in addition, it depends on the perspective from which it is valued. In this paper, the intention is to present an approach from the point of view of the architecture of the building itself, so that other aspects such as its astronomical equipment or its possible scientific usage will be set aside. That is to say, we will study the particularities related to the construction in which the instruments are located and whose purpose is the astronomical function. The analysis will also be limited to optical observatories.

Talking about evolution necessarily implies the extension of the study over time to analyze and assess how, when and why the changes that have defined the development of these astronomical centers have occurred. For this reason, following an earlier work (Castro-Tirado tro Tirado 2019a), starting from the examination of plans, ruins and the buildings themselves, this study goes back to the genesis of the observatories trying to illustrate the reciprocal relationship that exists between the design strategies of the building and the practice of its astronomical function, with the goal of theorizing about their future development. We have focused on 32 observatories which we consider to be representative ones in the period 1259-2007, deeply analyzing the architectural drafts.


2. ORIGINS

Astronomy is one of the oldest scientific disciplines of mankind. Since man raised his gaze to the sky and contemplated the stars with his own eyes, a relationship of fascination and devotion was established. This would be reflected in one way or another in different cultures that would arise across the planet. And even without having tools of precision or a basic understanding of the physical laws that rule the functioning of the universe, the first civilizations already had certain notions of the main astronomical facts. All based, always, on mere observations.

In any case, it is not possible to determine the date on which astronomy arises, although its roots probably extend to the origins of the human societies. What does seem clear is that, regardless of a spiritual or pseudo-religious sense, the beginnings of this science point towards an instrumentalization of the sky as a system for measuring periods of time and as a mean of orientation. Beyond the numerous artistic representations of the Sun, the Moon and the stars that have been found (Pannekoek 1961; Pasztor & Roslund 2007), sometimes more realistic and others more allegorical or figurative, or of the written testimonies that have lasted over time, this astronomical predilection remains through the incidence of some celestial phenomena in the disposition of certain archaeological sets.

Although certain remains of ancient civilizations show an impact of astronomy on their culture, it will be the proto-observatories that stand out as points of interest to know the way in which these peoples approached the practice of this science. In these spaces the astronomical observatories have their deepest antecedents and roots. Although the astronomical principles that underlie the constitution of these assemblies are undoubted, there is no evidence to support the existence of research or scientific work in these places.

The oldest site that has been recorded so far is the Goseck Circle, in Germany, a solar proto-observatory with an annular plan that consists of a Neolithic structure dating back almost 7000 years (Brown 2016; Scherrer 2018). Of a similar period is the megalithic group of Nabta Playa, in Egypt. There are many other cases of lesser antiquity, among which the temple of Mnajdra, in Malta, or the famed Stonehenge, in England (Scherrer 2018). All these sites belong to ancient societies, with a low degree of technology and even, frequently, of nomadic habits. These facts propitiate relatively simple identifications of their constructions. In addition, the scale and materials of these structures favor their durability up to the present, allowing them to be studied and identified, where relevant, as proto-observatories.

However, the evolution towards more advanced civilizations tend to create settlements of multiple buildings that do not reach the precise degree of specialization for the observation function as such. Since no scientific instruments had been developed that required demanding conditions, systematic surveying of the sky could be carried out with the naked eye in almost any construction or, even, in the vicinity of these out in the open.

The oldest building strictly dedicated to astronomy of which there is evidence is Cheomseongdae, in South Korea. It was designed as a small bottle-shaped hollow tower made of masonry. Its function was to enable the use of astronomical instruments from an elevated position to avoid surrounding obstacles. It dates from the seventh century and remains in a great state of preservation (Park 2010) and its square top and round body reflect the astronomical concept of the time (i.e. the Earth was considered a square and the sky was considered to have a round shape) with the 29 layers of stone from the bottom to the top corresponding to the 29.5 days of full lunation (or synodic month, i.e. the time from one new moon to the next) and the 27 layers of the round body representing the 27.3-day sidereal month, amongst other astronomical symbolism (Park 2008).

Anyway, although references to the Tower of Babel or to some type of astronomical institution directed by Ptolemy in Alexandria can be found (Mundt 1927; George 2005), there is no evidence to support the existence as such of pre-medieval astronomical observatories.


3. THE MEDIEVAL ISLAMIC OBSERVATORY

Coinciding with the beginning of the Middle Ages, a period of cultural darkness began in the Western world from which astronomy would not escape. During this period, Islamic culture came to play an essential role in the history of astronomy by preserving the vast Greek knowledge of this subject and incorporating its own findings. All this would be recovered for the West by the School of Translators of Toledo of Alfonso X, during the thirteenth century (Gargatagli 1999).

The medieval Islamic observing sites can indeed be called observatories because of two main reasons: i) the fact that they were spaces dedicated specifically to the collective and prolonged study of celestial phenomena and ii) to the exchange of scientific knowledge. It can be said that the observatory, as such, appears for the first time in this civilization. This is not a coincidence; the features of the Islamic culture as a society link with the observatory as a scientific institution (Sayili 1960). However, although this permanence is implemented in the Islamic observatory, they would have a reduced life (Sayili 1960).

Two singularities that would ultimately be decisive for the relevance of the Islamic observatory as an institution were the size of the observing tools and its patronage. The fact that the tools of observation and study reached a dimension such as to prevent their portability led to a necessary settlement. Royal or state support meant the formation of institutions larger and longer lived than an individual scientist (Sayili 1980).

Although several observing posts, more or less temporary, had previously been established, it is difficult to speak of observatories as an institution before Al Mamûn (ninth century). The numerous observations collected by different authors allow us to recognize centers established in Shammasiya, Baghdad and Mount Qasiyun, Damascus (Mujani et al. 2012). However, the fact that there are no remains, descriptions or illustrations of observatories could mean that no specific space was devoted to this use. This lack of material legacy makes it extremely difficult to distinguish between the observatories of this period and the specific observing posts established for an ephemeral study. The main differences amongst medieval islamic observatories were in the number of personnel dedicated to them, the quality of observing equipment and the life span of these centers. That is to say, at this initial moment the observatories were not a clearly defined institution and it is complicated to indicate which observation sites transcended the barrier between the most advanced temporary work post and the embryonic scientific center. It would be from this stage onward that the Islamic observatory began to develop as a specialized astronomical institution linked to a scientific team and a specific location. It then begins to be structured with its own administration around a work program and its instruments become more precise, larger and heavier.

All these circumstances suppose a change in the paradigm of the Islamic observatory that, in a hesitant process over several centuries, transcends from a semi-improvised observation post to the scientific reference center of its time. The construction of the observatory of Maragheh, in northwest Iran, was completed in 1264 and is part of the period that represents the climax of the evolution of the Islamic observatory (Saliba 1987). In fact, the main progress and features of this institution in the Islamic world appear with this observatory, which became the paradigm to imitate of its time.

Although only the ruins of the construction remain, these together with the existing testimonies (Sayili 1960) and the subsequent observatories built in its image, allow a description of the building to be developed. The observatory was a circular wall erected around a large central space occupied by the large quadrant for meridian transit observations. On both sides of this area there would be spaces to house the library, workshops, stores and other functions distinct from mere observation. Even though the date of the fall of the observatory at Maragheh is not exactly known, it still became the model to imitate by the great Islamic observatories that would arise during the following centuries, such as those of Samarkand and Istanbul.


4. THE MODERN OBSERVATORY

Although some references attribute the first European observatory to either Regiomontanus (Dreyer 1890; Gunther 1932) or Copernicus (Zinner 1943), there is no evidence of a construction or of fixed instruments that support these claims (Zinner 1943). There is a consensus to place the first modern observatory in the palace of Wilhelm IV of Hesse-Kassel (this is recognized by Todd 1922; Pannekoek 1961 or Pantin 1999). However, a platform built as a lookout point in the palace where portable instruments are taken out (Gaulke 2009) does not represent an advance from the perspective of architecture. This does not invalidate its importance since it was a visit to these facilities that inspired Tycho Brahe, a few months later, to build the first two modern observatories (Zinner 1956) in Hven characterized by having a certain degree of intention and architectural specialization for astronomy.

The first project of Tycho Brahe would be Uraniborg (1576), a palace in which the study of alchemy and astronomy would coexist with his own home. A dialogue between science and architecture in which the spatial configuration would adapt to the needs of research resulted in a solution that relegated alchemy to the basement and elevated astronomy to the upper floor, leaving the work and residence areas in the middle floor. Elevated platforms were built on slender poles from which it was possible to look at the sky without obstacles with covers that protected both the instruments and observers from poor weather conditions.

After several years Tycho Brahe noticed that the vibration of the platforms was being transmitted to the instruments and damaging the research unacceptably, so he planned a second center in which neither structural nor thermal instability would compromise astronomy. Following this idea Stjerneborg (1584) arose as a building excavated in the earth in which the observation tools would be fixed on pillars founded on the bedrock itself.

The appearance of the telescope in the early seventeenth century and its early connection with astronomy would condition the future design of observatories, in which the increase in accuracy would require improvements to avoid architecture from becoming a brake on scientific research. However, since the first telescopes were small and manageable, many astronomers could make their observations from the windows, balconies, terraces or gardens of their own residence, or from public spaces. Possibly, this is why, during this period, the development of astronomical centers tends towards simple structures or, directly, to adding platforms to existing buildings from which to get better views of the sky, as in the universities of Leiden (1632) and Ingolstadt (1637) or in the Danish Rundetårn (1637) (Donnelly 1971). Therefore, many years would pass between the appearance of the first modern observatory and the consolidation of the idea that a center for scientific observation required a building expressly designed for that purpose.

The observatory of Paris (1667) was created with the support of Louis XIV as a national institution in a context of increasing interest for culture and science. In addition to its scientific purpose, the project was to accommodate the headquarters of the Academy of Sciences and to enhance the prestige of its promoter. The resulting building is a palace where the institutional function shares space with the residences and the areas dedicated to astronomy: observation rooms, a zenith study room in the basement and a flat walkway for instruments. For more than a century, observatories followed the example of the French, limited to more or less contrived buildings that combined residence, work area and spaces where telescopes could operate. This is how the high observation rooms with vertical windows were reproduced, such as at the Greenwich Observatory (1675) or the openings from north to south were implemented at the Radcliffe Observatory (1772).

It was not until the construction of the Dunsink Observatory (1785) that significant changes were assimilated, where the architectural configuration was defined by the astronomical instruments that were to be installed. The person responsible for this project defined the key elements of the building as "situation, foundation and soil" (Ussher 1787). So the location was selected for its good visibility and accessibility, and the importance of stability meant the construction of foundations for the instruments to become structurally independent of the rest of the building. Systems were also developed to promote thermal stability in observation rooms. The design even reserves a privileged position to the telescopes, placing them under movable domes. The modern observatory is designed and planned to respond to a specific astronomical use during the period between the seventeenth and eighteenth centuries. The new observatories implement changes derived from the development of astronomy itself as a science (especially in relation to its instruments) and improve its performance for the sake of an optimal performance of the research activity without underestimating the welfare of its occupants.

Sometimes for strategic purposes (because of its importance for maritime navigation), sometimes for cultural ambition and in others, perhaps, by imitation, these buildings began to emerge throughout Europe in the eighteenth century, from where they would end up spreading to the rest of the world. Spaces for observation, characterized by the instruments that occupied them, coexisted with spaces in which the activities derived from these observations would take place (calculation, data analysis, discussion of results ...), secondary ones (preparation of instruments, offices, classrooms, libraries ...), and others corresponding to service uses (residences, storage areas ...) that, on occasion, moved to one or more independent buildings. Likewise, the scientific and technological progress of this period had an impact on the observatories: on the one hand the buildings incorporated new functions such as physics or chemistry laboratories, photographic work rooms or optical and mechanical workshops, while on the other hand the work of astronomers was facilitated by mechanizing the movement of domes and telescopes. In addition, technical advances allowed a growth of the refractor that led to a race to having the largest telescope in the world. This struggle reached its peak at the Yerkes Observatory (1897) where the size of the refractor (1.02 m diameter) entailed an increase in the architectural scale of the building (Hussey 1897).

Although in this period the trend led to the observatories to move away from the city and, therefore, the town, some centers would still emerge, such as the Allegheny (1912) or the Griffith (1925), which would open to the public offering the use of some instruments and other activities to disseminate and promote astronomy.


5. THE CONTEMPORARY OBSERVATORY

The development of cities from the nineteenth century began to cause problems in some nineteenth-century observatories, which not only began to withdraw from large cities to smaller settlements but also to seek locations far from urban areas. This withdrawal became increasingly necessary in the following decades, underlining a physical distance from the ordinary citizen that also led to an intellectual disconnection from astronomers until the press/media started to recover the connection amongst them in the 1960s. Astronomical centers with spaces such as conference halls, classrooms or exhibitions, open to visitors, amateurs and experts, or even public observatories, lost prominence in favor of highly specialized scientific complexes almost exclusively for astronomy.

The search for the highest possible precision from the instruments resulted in optimization of the observation conditions, which led to the establishment of these institutions in areas not affected by anthropogenic (light) pollution and with more favorable atmospheric conditions. The Lick Observatory (1881) was the first continuously inhabited mountain observatory in the world (Smiley 1938; Misch & Stone 1998). The location of the center was fundamentally based on its astronomical advantages, without regard of the distance to any city or university (Neubauer 1950). The architectural characteristics of the building are more like those of modern observatories than other contemporary observatories, which is why the Lick Observatory represents an intermediate, transitional case between the two epochs.

Almost simultaneously, the Nice Observatory (1881) emerged as a set of independent structures scattered over the top of a mountain. Each building was designed and located for a specific function, including the first building devoted entirely to a telescope. In this way, it pioneered the contemporary observatory layout of a set of specialized and independent buildings (Holden 1891; Etienne et al. 2014; Hünsch et al. 2012).

The size of the new large reflectors, the differences in scale, the different needs intrinsic to the multiple uses or the orography of the mountainous terrain that makes it difficult to have wide level soils, are aspects that drive the segregation of the initially unified observatory building into a series of independent structures. This separation allows for a freedom of disposition and orientation in the territory that will favor the conditions of observation, minimizing interference (vibrations, smoke, light, heating) that would compromise the quality of the astronomical observation.

Although mirror-based telescopes had been installed in observatories for decades, their role had always been secondary to that of large refractors. However, their importance increased thanks to technical advances that enabled the manufacture of the required mirrors in parallel with the development of astrophysics. In addition, the dissociation of the observatory buildings allowed the adaptation of the constructions to the instruments they housed without external constraints. An example of this is the Mount Wilson Observatory (1904), initially harboring the large 60-inch reflector and, later, in the 100-inch Hooker telescope (Adams 1954).

Ignoring the heterogeneous large-scale layout of the modern observatory, the contemporary design for an individual instrument is generally a base architectural structure scaled to the instrument it contains, topped by a movable cover, generally a dome. The size of telescopes reached such magnitudes that it rivaled the very scale of the architecture that had to contain it. This meant increasing the size of the buildings that housed the telescopes, producing a large amount of contained space available for other uses. Similarly, these large instruments require major structural supports, to such an extent that spaces inside the supports themselves can accommodate some functions.

Following the earlier Hooker telescope development, the Hale Telescope (1948) ended up consolidating different functions and hosting almost a thousand people during its opening ceremony. In this way, these large telescopes would incorporate or could incorporate enough secondary functions (offices, work canteens, meeting rooms, laboratories, warehouses, workshops, rest rooms, toilets ...) to be able to contain practically everything required for an entire observatory. Thus, the construction planned for each instrument would have sufficient autonomy to constitute an astronomical observatory by itself.

From this point on, the most important observatories were constituted as sets of independent structures where, habitually, they would include buildings for some accessory uses (residences, visitor areas ...), other structures allocated to secondary instruments, and the main buildings housing the great telescopes together with the primary functions (meeting rooms, work rooms, laboratories, offices ...), which would constitute the essence of the observatory.

The constant growth of the mirrors caused mechanical-structural problems in the BTA-6 (1975) (with a 6-meter primary mirror) that forced to introduce some fundamental changes in its design, adopting an alt-azimuth instead of an equatorial mount. This variation complicated the tracking of celestial objects, requiring a computerized control system. These two revolutionary advances were consolidated and replicated in later observatories (Leverington 2017). After the largest monolithic mirrors (8.2-meter diameter) were produced for the European Southern Observatory's Very Large Telescope (VLT, first light in 1998) (Schilling 1998) and Subaru (8.2 m), and the Large Binocular Telescope (8.4 m) later on, the planners of the W. M. Keck Observatory (1993/1996) decided to design the primary mirror as a combination of smaller mirrors to make ever-increasing mirror sizes possible. Correctly aligning segmented mirrors at that time represented a very hard problem. Because of this, for VLT a single-mirror approach was selected. Keck did indeed have control problems for years, vindicating the VLT decision. However, the experience of fixing Keck's problems paved the way for the future larger segmented mirrors telescopes.

The alt-azimuth design allowed for a significant reduction of the structures, which could be light, and the size of the domes, which would also reduce their cost (Finn 1985) compared to equatorially mounted telescopes. The race to the largest reflector paved the way to the Gran Telescopio Canarias (GTC, first light in 2007), with effective aperture of 10.4 m (composed of 36 segmented mirrors of 1.8 m diameter each) and inspired by the Keck. However, other projects are already underway that will exceed it in size but without significant changes in its configuration: the GMT (24.5m), the TMT (30m) or the ELT (39m).

Despite the changes experienced during this period, or even from the very origin of this institution, the importance of technological development in terms of computerization and communication systems must be highlighted as the causes of the greatest observatory revolution. Both the remote control and the remote access to the observations mark a decisive turning point regarding these complexes, since it seems to offer the possibility of abandoning all physical presence in the observatories. And although it is not necessary for an astronomer to look through a lens to access an observation, there are still a series of tasks derived from it that require a space in which scientists and engineers can work.


6. SPACE-FUNCTION ANALYSIS

Beyond this summary of the development of the observatory up to the present, anticipating the future evolution needs some analysis. Since it is difficult to evaluate all the variables that affect the constitution of these astronomical centers, this study focuses on the configuration of its architecture in relation to its uses, considering the evolution of astronomy and astronomical observing as a function of time. For this purpose, a classification is established for the different activities for which the different spaces of the buildings that house the instruments are intended. Observation spaces are considered to be those places occupied by active observation equipment, that is, they can be in operation if the environmental conditions make it possible. Research support spaces are those space that, though not directly participate in observations, provide functions necessary for astronomical work. Included in this category are work rooms, workshops, instrument warehouses, and so on. Finally, all of the dependencies that are not essential for astronomical research, such as conference rooms, rest areas, visitor galleries or exhibitions, are described as service spaces.

Based on this classification, we selected a representative sample (Figure 1) of astronomical centers that had the greatest impact and influence on other observatories of their time and afterwards. They are grouped according to the periods described in the previous sections and ordered chronologically and summarized in Table 1, which is based on the analysis of the plans and drafts of the different observatories together with information on how various spaces were used.


Figure 1. 
Lower or access levels of the case studies considered for the analysis of the programmatic-functional configuration in its evolution from the Islamic-medieval observatory to the contemporary one. The scale is the same in order to allow direct comparison. (Drawings by M. A. Castro-Tirado)

Table 1 
Percentages of surface areas of observatory buildings dedicated to different functions.
Observatory Area (m2) Observation (%) Derivatives (%) Accessories (%)
Maragheh (1259) 1164 4 96 0
Samarkand (1424) 3082 3 97 0
Uraniborg (1576) 1180 9 22 69
Stjerneborg (1584) 91 71 29 0
Paris (1667) 3152 48 8 44
Greenwich (1675) 501 25 4 71
Cádiz (1753) 1364 33 39 28
Madrid (1790) 618 27 14 59
Radcliffe (1772) 643 36 32 32
Dusink (1783) 802 21 27 52
Seeberg (1790) 473 13 4 83
Göttingen (1816) 1092 16 16 68
Hamburgo (1825) 627 18 19 63
Cape of Good Hope (1828) 355 26 3 61
Helsinki (1834) 1097 23 16 61
Harvard (1839) 744 29 20 51
Pulkovo (1839) 1429 44 18 38
U.S. Naval in Washington (1844) 367 26 40 34
Lisboa (1861) 893 40 10 50
Yerkes (1897) 2396 28 40 32
Allegheny (1912) 969 44 26 30
Lick (great refractor, 1881) 957 43 32 25
Niza (large equatorial, 1881) 1040 43 43 14
Mount Wilson (60-inch, 1908) 975 52 48 0
Mount Wilson (100-inch, 1917) 2509 51 49 0
Hamburg-Bergedorf (large refractor, 1912) 562 32 56 12
Palomar (Hale telescope, 1948) 1443 28 63 9
Lick (Shane reflector, 1959) 2108 33 60 7
SAO (BTA-6m, 1975) 4480 33 60 7
Calar Alto (3.5m, 1975) 3709 18 74 8
Keck (1993) 3873 49 47 4
Gran Telescopio Canarias (2007) 3457 24 70 6

Our work shows how the aspects defined in the different periods have their corresponding manifestation in this classification. This highlights the weak correlation between the Islamic observatory and the modern observatory. In addition, during the beginnings of the modern observatory (between the Uraniborg and Dunsink cases) there is a period of continuous changes in the distribution of uses, probably related to the different types of instrumentation and observing techniques used. However, since its consolidation (since Seeberg) a tendency has emerged regarding the development of its organization that extends to the current contemporary observatory.

On the one hand, Figure 2 shows a tendency toward an increase of the fraction occupied by research support spaces over time. That means a higher proportion of area in which astronomers and technicians can actually work (offices, laboratories, workshops ...), which suggests how the complexity of the instruments attached to the telescopes has increased as time went on. It underscores the growing importance of these functions for achieving results in research.


Figure 2. 
Fractions of the surface areas allocated to research support spaces in the observatories in our sample.

On the other hand, as shown in Figure 3, the fraction occupied by service spaces decreases with time. This can be due to a greater specialization of these buildings as they suppress some functions not strictly astronomical (rest areas, cafeterias, exhibition halls or visitors centers) which may be relegated to secondary structures.


Figure 3. 
Fractions of the surface areas dedicated to service spaces in the observatories in our sample.

An important reason for the scattered or segregated pattern of modern observatories is the addition of new projects after the initial foundation. Good sites are rare, getting water, electricity and roads to that site may be the single most expensive part of the project. By comparison, adding further instruments to an established site is often a minor expense. Also, in terms of project planning, existing observatories have a science-grade record of the local weather, eliminating the need for possibly several years of site monitoring to establish whether a new proposed site is good enough.


7. THE FORTHCOMING OBSERVATORY

Since its inception, the astronomical observatory has reflected a continuous architectural adaptation of the building to the needs of astronomy. Thus, aspects such as structural stability, thermal stability, orientation of the construction, the specific configuration of windows, the adaptation to the different astronomical instruments, the generation of service and comfort spaces for the users of the observatory, the incorporation of new functions derived from the advances of science, the change of scale according to the growth of the instruments, the adaptation to non-urban geographic environments or the conciliation with new technologies have been addressed.

Obviously the current observatories, of the beginning of the 21st century, are vastly different from their modern or Islamic-medieval ancestors. Nor are they the same as those of the mid-twentieth century, even though the influence of the Hale Telescope has spread through all the astronomical centers that succeeded it. In any case, this evolution is not taking place in an intentional or planned way, but the changes take place in an organic and almost improvised way. This, which is not a problem in itself, does denote a lack of deep understanding regarding observatories, understood as buildings in which astronomical research and human activity coexist and relate through architecture. All this means that occasionally some of the different functions of the observatory come into conflict with each other, indicating a certain lack of criticism and reflection. It is difficult to answer clearly and unequivocally where astronomical observatories are heading, since there does not seem to be a roadmap that points in a clear direction, due to the fact that technological advances are unpredictable.


8. CONCLUSIONS

Although the selection of astronomical observatories analyzed in this work could include a larger sample, it would not significantly change the result since the architecture and configuration of the buildings was frequently replicated with few variations.

In any case, our investigation has found evidence for two opposite directions of evolution:

  • • continuation of the dissociation of astronomical instruments from other functions related to research;
  • • return to heterogeneous uses of space in the same building such that the needs of its users can match the astronomical activity.

The first of these possibilities would involve a split of what is now known as an observatory. The result is a pair of buildings, one of which houses all the spaces and dependencies necessary for the staff to do their research (laboratories, offices, etc.), all the elements that could result in better comfort for workers (cafeteria, dining room, rest areas, etc.). In addition, this property should also house all kinds of technical rooms (control rooms, workshops ...) or accessories (facilities, warehouses ...) that would serve the astronomical function. The second building, separate and independent, would be completely unrelated to human activity (for example, the electricity supply).

The second possibility would involve unifying in a single building both the strictly intrinsic functions of astronomical research and the rest of the uses and services associated with the workers of the center or even visitors. For this, it would be necessary to carefully consider and correct the possible interference and incompatibilities between the different uses. This would result in a rather complex single construction.

When planning a new observatory in an area where other research centers are concentrated, it would be reasonable to choose a structure for the new telescope that would be separated from a place for workers and other users that could even be shared with other facilities and neighbors. However, opting for a unitary building would be adequate if the new observatory considers aspects beyond pure research (such as teaching or public outreach) or if the project were to be implemented in a remote and isolated place, saving resources and optimizing supply lines.

Overall it seems reasonable that the two opposite directions of evolution can coexist in the near future where they could represent the most appropriate solutions in different scenarios; see also Castro Tirado (2019b).


Acknowledgments

We have profited from valuable discussions with Ronan Cunniffe and Gemma Olmedo Paradas. We are grateful to Luis Alberto Rodríguez and Antonio Cabrera-Lavers (Gran Telescopio Canarias), Cristina Rodríguez (Observatorio de Sierra Nevada), Santos Pedraz (Calar Alto Observatory) and Tatyana Sokolova (Special Astrophysical Observatory) for providing the requested material and pictures of the astronomical observatories they are related to. We also acknowledge very useful comments from the two anonymous referees. M. A. C. T. has been supported by a Junta de Andalucía predoctoral grant under project TIC-2839. Finally, we also acknowledge financial support from the State Agency for Research of the Spanish MCIU through the "Center of Excellence Severo Ochoa" award for the Instituto de Astrofísica de Andalucía (SEV-2017-0709).


References
1. Adams, W. S., (1954), The Founding of The Mount Wilson Observatory, PASP, 66, p267.
2. Brahe, T., (1602), Astronomiae Instauratae Mechanica, Nuremberg.
3. Brown, D., (2016), An Introductory View on Archaeoastronomy, J. Phys. Conf. Ser., 685, p2.
4. Caramuel de Lobkowitz, J., (1678), Architectura Civil Recta y Obliqua, Vigevano, Imprenta Obispal.
5. Castro Tirado, M. A., (2019a), Astronomical Observatories: From the Prehistory to the XVIIIth Century, RMxAA Conf. Ser., 51, p1.
6. Castro Tirado, M. A., (2019b), El Observatorio Astronómico: Un Diálogo entre Ciencia y Arquitectura, Ph.D. Thesis, University of Málaga.
7. Donnelly, M. C., (1971), A Short History of Observatories, Eugene, University of Oregon Books.
8. Dreyer, J. L. E., (1890), Tycho Brahe, Edinburgh, A. & C. Black.
9. Dumitrache, C., & Dumitrache, D., (2009), Architectural Evolution of Astronomical Observatories, Romanian Astron. J., 19, p1.
10. Etienne, C., et al., (2014), L'Observatoire de la Côte d'Azur et sa Mission de Diffusion de la Culture Scientifique et Technique, infos-patrimoinespaca.org.
11. Finn, R., (1985), The WM Keck Observatory, Engin. Sci., 48, p5.
12. Gargatagli, M., (1999), La Escuela de Traductores de Toledo, Quaderns. Revista de Traducció, 4, p9.
13. Gaulke, K., (2009), The first European Observatory of the Sixteenth Century, as Founded by Landgrave Wilhelm IV of Hesse-Kassel: a Serious Historiographic Category or a Misleading Marketing Device?, in, Strano, G., et al., (eds.), European Collection of Scientific Instruments 1550-1750, Leiden, Brill.
14. George, A., (2005), The Tower of Babel: Archaeology, History and Cuneiform Texts, Archiv für Orientforschung, 51, p75.
15. Gunther, R. T., (1932), Early Science in Oxford, Oxford, Oxford University Press.
16. Holden, E. S., (1891), The Observatory of Nice, PASP, 3, p123.
17. Hünsch, M., Seemann, A., & Wolfschmidt, G., (2012), The Hamburg Observatory, Justification of Outstanding Universal Value, Freie und Hansestadt Hamburg / Kulturbeh örde / Denkmalschutzamt.
18. Hussey, W. J., (1897), The Yerkes Observatory, PASP, 59, p220.
19. Krisciunas, K., (1999), Observatories, Cornell University Library, arXiv:astro-ph/9902030.
20. Kwan, A. M., (2012), Architectures of Astronomical Observation: from Sternwarte Kassel (circa 1560) to Radcliffe Observatory (1772), PhD Thesis, Yale University.
21. Leverington, D., (2017), Observatories and Telescopes of Modern Times, Cambridge, Cambridge University Press.
22. Misch, A., & Stone, R., (1998), Building the Observatory, Web of The Lick Observatory Historical Collections, collections.ucolick.org.
23. Mujani, W. K., et al., (2012), Observatories in Islamic History, Adv. Nat. Appl. Sci., 6, p1370.
24. Mundt, C. S., (1927), Notable Astronomers of Past Ages. II - Ptolemy, PASP, 39, p122.
25. Neubauer, F. J., (1950), A Short History of the Lick Observatory, Pop. Astron., 58, p200.
26. Pannekoek, A., (1961), A history of Astronomy, New York, Dover.
27. Pantin, I., (1999), New Philosophy and Old Prejudices: Aspects of the Reception of Copernicanism in a Divided Europe, Studies Hist. Philos. Sci., 30, p237.
28. Park, C., (2008), Astronomy: Traditional Korean Science, Seoul, Ewha Womans University.
29. Park, J. E., (2010), Cheomseongdae Observatory, Republic of Korea, in, Ruggles, C., & Cotte, M., (eds.), Heritage Sites of Astronomy and Archaeoastronomy in the Context of the UNESCO World Heritage Convention, Paris, ICOMOS/IAU, 96, whc.unesco.org.
30. Pasztor, E., & Roslund, R., (2007), An Interpretation of the Nebra Disc, Antiquity, 81, p267.
31. Saliba, G., (1987), The Role of Maragha Observatory in the Development of Islamic Astronomy: a Scientific Revolution before the Renaissance, Revue de Synthèse, 108, p361.
32. Sayili, A., (1960), The Observatory in Islam and its Place in the General History of Astronomy, Ankara, Türk Tarih Kurumu Basimevi.
33. Sayili, A., (1980), The International Symposium on the Observatories in Islam, 19-23 Sep 1977 (Istanbul, Ed. Dizer).
34. Scherrer, D., (2018), Ancient Observatories, Timeless Knowledge, Stanford University, solar-center.stanford.edu.
35. Schilling, G., (1998), World's Biggest Telescope Is About to See the Light, Science, 280, p670.
36. Smiley, C. H., (1938), The History of the Lick Observatory, Sci. Monthly, 47, p128.
37. Todd, D., (1922), Astronomy: the Science of the Heavenly Bodies, London, Harper & Brothers.
38. Ussher, H., (1787), The Transactions of the Royal Irish Academy, Dublin, Royal Irish Academy, 1, p3.
39. Waumans, A. A., (2013), The Typology of Astronomical Observatories, Ph.D. Thesis, Delft University of Technology.
40. Wolfschmidt, G., (ed.), (2008), Cultural Heritage of Astronomical Observatories, From Classical Astronomy to Modern Astrophysics, Hamburg, ICOMOS.
41. Zinner, E., (1943a), Entstehung und Ausbreitung der Copernikanischen Lehre, Erlangen, Max Mencke.
42. Zinner, E., (1956), Astronomische Instrumente des 11. bis 18. Jahrhunderts, Munich, C. H. Beck.