ROMAN SURVEYING - TRAIANVS

1 Isaac Moreno Gallo _____. ROMAN SURVEYING . First Published as Elementos de ingenier a romana [Elements of ROMAN engineering], Proceedings of the European congress Las obras p blicas romanas [ ROMAN public Works]. ISBN Tarragona, 3-6 November, 2004. Isaac Moreno Gallo 2004. Translated by Brian R. Bishop 2006. TRAIANVS 2006. ANCIENT TECHNOLOGY .. 2. Forerunners .. 3. Thales of Miletus .. 3. Pythagoras .. 5. Euclid .. 6. Apollonius .. 6. Archimedes .. 6. 7. Heron of Alexandria .. 8. Ptolemy .. 8. The spatial concept .. 9. INSTRUMENTS .. 12. String .. 12. Chains .. 13. Decempeda or pertica (perch).

2 14. 14. Range poles .. 15. 15. Surveyor's square .. 19. Gnomon .. 22. Libra Aquaria .. 25. Chorobate or leveller .. 25. Diopter .. 33. Lychnia or lamp-standard .. 36. TECHNIQUES .. 37. Land measurement, geodesy and triangulation.. 39. SURVEYING .. 43. Laying out main roads.. 44. Channelling water and levelling techniques .. 45. Drilling of galleries.. 49. CONCLUSION .. 54. BIBLIOGRAPHY.. 54. ROMAN SURVEYING P gina 1 de 55. Isaac Moreno Gallo _____. AIM. ROMAN engineering works are distinguished in particular by their use of very careful measurements. Main roads follow long straight lines with gentle gradients wherever the terrain allows.

3 Cities and fields are strictly squared off, sometimes over extremely large areas. However, it is probable that it is the aqueducts, those lengthy conduits that brought water from natural springs and other water sources to the cities for human consumption, that reach the high point of geometric perfection, simply because it was essential to their functioning. In analyzing their planning and construction processes, we have been struck with doubts as to the way in which ROMAN engineers could have surveyed and constructed each piece with precision on site. These works were at times so complex to carry out, even with today's techniques, as to require the greatest skill and greatest care in planning to ensure they functioned properly.

4 The time spent in these studies has been encouraged to a large extent by the little that is known and by how unconvincing are pronouncements on ROMAN SURVEYING , mainly in modern writings. This work explains how our thoughts on the subject have developed. At the same time as we describe some of the instruments that we have reconstructed, their functioning and the results of our experiences in using them, we shall summarize briefly some of the techniques that, being well within the capabilities of ROMAN technicians, could have been used successfully in their engineering works.

5 ANCIENT TECHNOLOGY. ROMAN engineers gained most of their knowledge to resolve problems of measurement and calculation from Greece. And not only ROMAN engineers, but also those of Renaissance Europe used ancient texts to advance the meager science inherited directly from the Middle Ages. Juan de Herrera was the first to be in charge of setting up the first scientific academies in the Spain of Philip II 1. It is noteworthy how Juan de Herrera specifies the books and texts to be read in order to meet his the student's objectives. For example, he instructs those who wish to become arithmeticians to know "the nine books of Euclid, some other theoretical arithmetic, such as Jordanus Nemorarius (1225-1260) or Bo thius (c.)

6 480-524), and the practical aspects to be taken out of the works of Frate Luca Pacioli (1445-1517) or Niccolo Cartaglia (c. ); those who intend to become geometricians and surveyors "must know the first books of Euclid, the doctrine of triangles of Regiomontanus (Johann M ller, 1436-1476), the last five books of Euclid, including book X, Sphaerica of Theodosius ( century ), Conics by Apollonius of Perga (c. 3rd century ), and the works of Archimedes ( ) on the sphere and the cylinder". At the same time, those who intended to dedicate themselves to mechanics as well as astrologers, gnomonists, perspectivers, musicians, architects, fortification engineers, surveyors, gunnery experts, needed to know Euclid's Geometry as well as other listed specialist works.

7 Particularly interesting is the case of cosmographers and pilots, for whom it was considered essential to know the Sphere and the Theories of the planets and to understand in depth Ptolemy's Geography, together with the use of maritime charts, the astrolabe, the ballista and the compass. To these ends, Pedro Ambrosio de Ond riz ( ?-1596) translated in just a year the following works (in Juan de Herrera's own words): "The eleventh and twelfth books of Euclid, the Perspectives and Reflexions printed at his own expense, the Sphaerica of Theodosius, the Equilibria of Archimedes, and he is in the process of finishing another book entitled Apollonius of Perga".

8 1. ESTEBAN PI ERO, M. 2003. Las Academias T cnicas en la Espa a del siglo XVI. Quaderns d'Hist ria de l'Enginyeria Volum V 2002-2003. ROMAN SURVEYING P gina 2 de 55. Isaac Moreno Gallo _____. So, the main knowledge on which ROMAN surveyors relied, as well as the present-day surveyors, was the part of mathematics known as trigonometry. Trigonometry relates the angles of a triangle to its sides. It can be said that it was started by Hipparchus (fl. 146-127 ). Others followed him until Ptolemy took over. Then, as now, engineers and physicists use many of their tools in their day-to-day work.

9 The two main branches of trigonometry are plane trigonometry, dealing with shapes in a plane, and spherical trigonometry, dealing with the triangles that go to make up the surface of a sphere. Both aspects were well mastered in antiquity, since this branch of knowledge goes back to Egyptian and Babylonian mathematicians, the Egyptians being the first to measure angles in degrees, minutes and seconds. However, let us here examine the work in this subject by the scientists of antiquity of whom we have knowledge. Forerunners Thales of Miletus It is probable that his work has had the greatest influence on the science of measuring in the West.

10 He was born around the year 624 and he died between 548 and 545 As a philosopher he is remembered mainly for his Cosmology, based on water being the essence of all matter, and for his forecasting the eclipse of the sun which must have occurred on 28th May, 585. No writings of Thales survive, nor contemporary sources on him, that could serve as references. This makes it exceedingly difficult to know the extent of what he achieved. It is even more difficult, because in ancient Greece it was usual to ascribe many discoveries to people upheld as experts, without their having been involved.