Mathematics Physics Pneumatic and hydraulic engineering
Hero of Alexandria (/ˈhɪəroʊ/;
Greek: Ἥρων[1] ὁ Ἀλεξανδρεύς, Hērōn hò Alexandreús, also known as Heron of Alexandria/ˈhɛrən/;
fl. 60 AD) was a
Greco-Roman mathematician and
engineer who was active in his native city of
Alexandria in Egypt during the Roman era. He is often considered the greatest experimenter of antiquity[2] and his work is representative of the
Hellenistic scientific tradition.[3]
Hero published a well-recognized description of a
steam-powered device called an aeolipile (sometimes called a "Hero engine"). Among his most famous inventions was a
windwheel, constituting the earliest instance of
wind harnessing on land.[4][5] He is said to have been a follower of the
atomists. In his work Mechanics, he described
pantographs.[6] Some of his ideas were derived from the works of
Ctesibius.
In mathematics he is mostly remembered for
Heron's formula, a way to calculate the area of a triangle using only the lengths of its sides.
Much of Hero's original writings and designs have been
lost, but some of his works were preserved including in manuscripts from the Eastern Roman Empire and to a lesser extent, in Latin or Arabic translations.
Life and career
Hero's ethnicity may have been either
Greek[2] or
HellenizedEgyptian.[7] It is almost certain that Hero taught at the
Musaeum which included the famous
Library of Alexandria, because most of his writings appear as lecture notes for courses in
mathematics,
mechanics,
physics and
pneumatics. Although the field was not formalized until the twentieth century, it is thought that the work of Hero, in particular his automated devices, represented some of the first formal research into
cybernetics.[8]
Inventions
Hero described[9] the construction of the aeolipile (a version of which is known as Hero's engine) which was a
rocket-like reaction engine and the first-recorded
steam engine (although
Vitruvius mentioned the aeolipile in De Architectura some 100 years earlier than Hero). It was described almost two millennia before the
industrial revolution. Another engine used air from a closed chamber heated by an altar fire to displace water from a sealed vessel; the water was collected and its weight, pulling on a rope, opened temple doors.[10] Some historians have conflated the two inventions to assert that the aeolipile was capable of useful work, which is not entirely false, air containing a trace of water vapor.[clarification needed] However, this engine is far from a pure aeolipile.[11]
The first
vending machine was also one of his constructions; when a coin was introduced via a slot on the top of the machine, it dispensed a set amount of water for ablutions. This was included in his list of inventions in his book Mechanics and Optics. When the coin was deposited, it fell upon a pan attached to a lever. The lever opened up a valve which let some water flow out. The pan continued to tilt with the weight of the coin until it fell off, at which point a counter-weight would snap the lever back up and turn off the valve.[12]
A wind-wheel operating an organ, marking the first instance in history of wind powering a machine.[4][5]
Hero also invented many mechanisms for the Greek
theatre, including an entirely mechanical play almost ten minutes in length, powered by a binary-like system of ropes, knots, and simple machines operated by a rotating cylindrical cogwheel. The sound of
thunder was produced by the mechanically-timed dropping of metal balls onto a hidden drum.
The
force pump was widely used in the
Roman world, and one application was in a fire engine.
A
syringe-like device was described by Hero to control the delivery of air or liquids.[13]
In optics, Hero formulated the
principle of the shortest path of light: If a ray of light propagates from point A to point B within the same medium, the path-length followed is the shortest possible. It was nearly 1,000 years later that
Alhacen expanded the principle to both reflection and refraction, and the principle was later stated in this form by
Pierre de Fermat in 1662; the most modern form is that the optical path is
stationary.
A stand-alone fountain that operates under self-contained hydro-static energy; now called
Heron's fountain.
A cart that was powered by a falling weight and strings wrapped around the drive axle.[14]
Various authors have credited the invention of the
thermometer to Hero. The thermometer was
not a single invention, however, but a development. Hero knew of the principle that certain substances, notably air, expand and contract and described a demonstration in which a closed tube partially filled with air had its end in a container of water.[15] The expansion and contraction of the air caused the position of the water/air interface to move along the tube.
Hero described a method, now known as
Heron's method, for iteratively computing the
square root of a number.[17] Today, however, his name is most closely associated with
Heron's formula for finding the area of a triangle from its side lengths. He also devised a method for calculating cube roots.[18] He also designed a shortest path algorithm, that is, given two points A and B on one side of a line, find C a point on the straight line that minimizes AC+BC.
In
Arthur C. Clarke's 1953 novel Childhood's End, a model of the turbine is present in the Earth exhibit of the Overlords' museum of alien cultures.
A 1979 Soviet animated short film focuses on Hero's invention of the aeolipile, showing him as a plain craftsman who invented the
turbine accidentally.[19]
Bibliography
The most comprehensive edition of Hero's works was published in five volumes in Leipzig by the publishing house Teubner in 1903.
Automata, a description of machines which enable wonders in banquets and possibly also theatrical contexts by mechanical or pneumatical means (e.g. automatic opening or closing of temple doors, statues that pour wine and milk, etc.)[21]
Mechanica, preserved only in Arabic, written for
architects, containing means to lift heavy objects
Metrica, a description of how to calculate
surfaces and
volumes of diverse objects
On the Dioptra, a collection of methods to measure lengths, a work in which the
odometer and the
dioptra, an apparatus which resembles the
theodolite, are described
^
abResearch Machines plc. (2004). The Hutchinson dictionary of scientific biography. Abingdon, Oxon: Helicon Publishing. p. 546. Hero of Alexandria (lived c. AD 60) Greek mathematician, engineer and the greatest experimentalist of antiquity
^Marie Boas, "Hero's Pneumatica: A Study of Its Transmission and Influence", Isis, Vol. 40, No. 1 (Feb., 1949), p. 38 and supra
^
abA.G. Drachmann, "Heron's Windmill", Centaurus, 7 (1961), pp. 145–151
^
abDietrich Lohrmann, "Von der östlichen zur westlichen Windmühle", Archiv für Kulturgeschichte, Vol. 77, Issue 1 (1995), pp. 1–30 (10f.)
^Victor J. Katz (1998). A History of Mathematics: An Introduction, p. 184. Addison Wesley,
ISBN0-321-01618-1: "But what we really want to know is to what extent the Alexandrian mathematicians of the period from the first to the fifth centuries C.E. were Greek. Certainly, all of them wrote in Greek and were part of the Greek intellectual community of Alexandria. And most modern studies conclude that the Greek community coexisted [...] So should we assume that Ptolemy and Diophantus, Pappus and Hypatia were ethnically Greek, that their ancestors had come from Greece at some point in the past but had remained effectively isolated from the Egyptians? It is, of course, impossible to answer this question definitively. But research in papyri dating from the early centuries of the common era demonstrates that a significant amount of intermarriage took place between the Greek and Egyptian communities [...] And it is known that Greek marriage contracts increasingly came to resemble Egyptian ones. In addition, even from the founding of Alexandria, small numbers of Egyptians were admitted to the privileged classes in the city to fulfill numerous civic roles. Of course, it was essential in such cases for the Egyptians to become "Hellenized," to adopt Greek habits and the Greek language. Given that the Alexandrian mathematicians mentioned here were active several hundred years after the founding of the city, it would seem at least equally possible that they were ethnically Egyptian as that they remained ethnically Greek. In any case, it is unreasonable to portray them with purely European features when no physical descriptions exist."
^Hero (1899).
"Pneumatika, Book ΙΙ, Chapter XI". Herons von Alexandria Druckwerke und Automatentheater (in Greek and German). Wilhelm Schmidt (translator). Leipzig: B.G. Teubner. pp. 228–232.
^Hero of Alexandria (1851).
"Temple Doors opened by Fire on an Altar". Pneumatics of Hero of Alexandria. Bennet Woodcroft (trans.). London: Taylor Walton and Maberly (online edition from University of Rochester, Rochester, NY). Archived from
the original on 2008-05-09. Retrieved 2008-04-23.
^For example:
Mokyr, Joel (2001). Twenty-five centuries of technological change. London: Routledge. p. 11.
ISBN0-415-26931-8. Among the devices credited to Hero are the aeolipile, a working steam engine used to open temple doors and Wood, Chris M.; McDonald, D. Gordon (1997). "History of propulsion devices and turbo machines". Global Warming. Cambridge, England: Cambridge University Press. p. 3.
ISBN0-521-49532-6. Two exhaust nozzles...were used to direct the steam with high velocity and rotate the sphere...By attaching ropes to the axial shaft Hero used the developed power to perform tasks such as opening temple doors
^Humphrey, John W.; John P. Oleson; Andrew N. Sherwood (1998). Greek and Roman technology: A Sourcebook. Annotated translations of Greek and Latin texts and documents. Routledge Sourcebooks for the Ancient World. London and New York: Routledge.
ISBN978-0-415-06137-7., pp. 66–67
^Russo, Lucio (2004). The Forgotten Revolution : How Science Was Born in 300 BC and Why it Had to Be Reborn. Translated by Levy, Silvio (1 ed.). Berlin, Heidelberg: Springer Berlin Heidelberg.
ISBN978-3-642-18904-3.
Roby, Courtney Ann (2023). The mechanical tradition of Hero of Alexandria: strategies of reading from antiquity to the early modern period. Cambridge; New York: Cambridge University Press.
ISBN9781316516232.