''On the Equilibrium of Planes'' ( grc, Περὶ ἐπιπέδων ἱσορροπιῶν, translit=perí epipédōn isorropiôn) is a treatise by

Archimedes Archimedes of Syracuse (;; ) was a Greek mathematician, physicist, engineer, astronomer, and inventor from the ancient city of Syracuse in Sicily. Although few details of his life are known, he is regarded as one of the leading scientists i ...

in two volumes. The first book contains a proof of the

law of the lever A lever is a simple machine consisting of a beam or rigid rod pivoted at a fixed hinge, or ''fulcrum''. A lever is a rigid body capable of rotating on a point on itself. On the basis of the locations of fulcrum, load and effort, the lever is div ...

and culminates with propositions on the

centre of gravity In physics, the center of mass of a distribution of mass in space (sometimes referred to as the balance point) is the unique point where the weighted relative position of the distributed mass sums to zero. This is the point to which a force may ...

of the

triangle A triangle is a polygon with three edges and three vertices. It is one of the basic shapes in geometry. A triangle with vertices ''A'', ''B'', and ''C'' is denoted \triangle ABC. In Euclidean geometry, any three points, when non-collinear ...

and the trapezium. The second book, which contains ten

propositions In logic and linguistics, a proposition is the meaning of a declarative sentence. In philosophy, " meaning" is understood to be a non-linguistic entity which is shared by all sentences with the same meaning. Equivalently, a proposition is the no ...

, examines the centres of gravity of parabolic segments. According to

Pappus of Alexandria Pappus of Alexandria (; grc-gre, Πάππος ὁ Ἀλεξανδρεύς; AD) was one of the last great Greek mathematicians of antiquity known for his ''Synagoge'' (Συναγωγή) or ''Collection'' (), and for Pappus's hexagon theorem i ...

, Archimedes' work on levers caused him to say: "Give me a place to stand on, and I will move the Earth" ( grc, δός μοί ποῦ στῶ καὶ κινῶ τὴν γῆν, translit=dṓs moi poû stṓ kaí kinô tḗn gên, links=no), though other ancient testimonia are ambiguous regarding the context of the saying.

Overview

The lever and its properties were already well known before the time of Archimedes, and he was not the first to provide an analysis of the principle involved. The earlier '' Mechanical Problems'', once attributed to Aristotle but most likely written by one of his successors, contains a loose proof of the law of the lever without employing the concept of centre of gravity. There is another short work attributed to

Euclid Euclid (; grc-gre, Εὐκλείδης; BC) was an ancient Greek mathematician active as a geometer and logician. Considered the "father of geometry", he is chiefly known for the ''Elements'' treatise, which established the foundations of ge ...

entitled ''On the Balance'' that also contains a mathematical proof of the law, again without recourse to the centre of gravity. In contrast, in Archimedes' work the concept of the centre of gravity is crucial. ''On the Equilibrium of Planes'' I, which contains seven postulates and fifteen propositions, uses the centre of gravity for both commensurable and incommensurable magnitudes to justify the law of the lever, though some argue not satisfactorily. Archimedes then proceeds to locate the centre of gravity of the

parallelogram In Euclidean geometry, a parallelogram is a simple (non- self-intersecting) quadrilateral with two pairs of parallel sides. The opposite or facing sides of a parallelogram are of equal length and the opposite angles of a parallelogram are of equ ...

and the

, ending book one with a proof on the centre of gravity of the trapezium. ''On the Equilibrium of Planes'' II shares the same subject matter as the first book but was most likely written at a later date. It contains ten propositions regarding the centre of gravity of parabolic segments exclusively, and examines these segments by substituting them with rectangles of equal area. This exchange is made possible by results obtained in ''

Quadrature of the Parabola ''Quadrature of the Parabola'' ( el, Τετραγωνισμὸς παραβολῆς) is a treatise on geometry, written by Archimedes in the 3rd century BC and addressed to his Alexandrian acquaintance Dositheus. It contains 24 propositions regar ...

'', a treatise believed to have been published after book one of ''On the Equilibrium of Planes''.''''

Book one

The first half of book one deals with the properties of the balance and the law of the lever, while the second half focuses on the centre of gravity of basic plane figures. The argument that establishes the law of the lever makes use in particular of the first postulate, which states that "equal weights at equal distances are in equilibrium". In Propositions 4 and 5, Archimedes expands on this postulate by proving that the centre of gravity of any system consisting of an even number of equal weights, equally distributed, will be located at the midpoint between the two centre weights. Archimedes then uses these theorems to prove the law of the lever in Proposition 6 (for commensurate cases) and Proposition 7 (for incommensurate cases). Proof Equilibrium Planes Weights Line

Given two unequal, but commensurable, weights and a lever arm divided into two unequal, yet commensurable, portions (see sketch opposite), if the magnitudes A and B are applied at points E and D, respectively, the system will be in equilibrium if the weights are inversely proportional to the lengths: :

A : B = CD : EC\,

Let us assume that lines and weights are constructed to obey the rule using a common measure (or unit) N, and at a ratio of four to three. Now, double the length of ED by duplicating the longer arm on the left, and the shorter arm on the right. Equilibrium Planes Extended Line

For demonstration's sake, reorder the lines so that CD is adjacent to LE (the two red lines together), and juxtapose with the original (as below): Equilibrium Planes Compared Lines

It is clear that both lines are double the length of the original line ED, that LH has its centre at E, and that HK has its centre at D. Note, additionally, that EH (which is equal to CD) carries the common measure (or unit) N an exact number of times, as does EC and, by extension, CH. It remains then to prove that A applied at E, and B applied at D, will have their centre of gravity at C. Therefore, as the ratio of LH to HK has doubled the original distances CD and EC, similarly divide the magnitudes A and B into a ratio of eight to six (a transformation that conserves their original ratio of four to three), and align them so that the A units (red) are centred on E, while the B units (blue) are centred on D. Equilibrium Planes Applied Weights

Now, since an even number of equal weights, equally spaced, have their centre of gravity between the two middle weights, A is in fact applied at E, and B at D, as the proposition requires. Further, the total system consists of an even number of equal weights equally distributed, and, therefore, following the same law, C must be the centre of gravity of the full system. Thus, the system does not incline but is in equilibrium.

Book two

The main objective of book two of ''On the Equilibrium of Planes'' is the determination of the centre of gravity of any part of a parabolic segment, as shown in Proposition 8. The book begins with a simpler proof of the law of the lever in Proposition 1, making reference to results found in ''

''. Archimedes proves the next seven propositions by combining the concept of centre of gravity and the properties of the parabola dealt with in book one of ''On the Equilibrium of Planes''. More importantly, he infers that two parabolas equal in area have their centre of gravity equidistant from some point, and later substitutes their areas with rectangles of equal area. The last two propositions, Propositions 9 and 10, are rather obtuse but focus on the determination of the centre of gravity of a figure cut off from any parabolic segment by a

frustum In geometry, a (from the Latin for "morsel"; plural: ''frusta'' or ''frustums'') is the portion of a solid (normally a pyramid or a cone) that lies between two parallel planes cutting this solid. In the case of a pyramid, the base faces are ...

. Republished translation of the 1938 study of Archimedes and his works by an historian of science.

Legacy

Archimedes' mechanical works, including ''On the Equilibrium of Planes'', were known but little read in antiquity. Both

Hero A hero (feminine: heroine) is a real person or a main fictional character who, in the face of danger, combats adversity through feats of ingenuity, courage, or strength. Like other formerly gender-specific terms (like ''actor''), ''hero ...

and Pappus quote Archimedes extensively in their work on mechanics, mostly in their discussions regarding the centre of gravity and

mechanical advantage Mechanical advantage is a measure of the force amplification achieved by using a tool, mechanical device or machine system. The device trades off input forces against movement to obtain a desired amplification in the output force. The model for t ...

. A few Roman authors, such as

Vitruvius Vitruvius (; c. 80–70 BC – after c. 15 BC) was a Roman architect and engineer during the 1st century BC, known for his multi-volume work entitled ''De architectura''. He originated the idea that all buildings should have three attribute ...

, apparently had some knowledge of his work as well. In the Middle Ages, some Arabic authors were familiar with and extended Archimedes' work on balances and centre of gravity; in the Latin West, however, these ideas were virtually unknown except for a handful of limited cases. It is only in the

Renaissance The Renaissance ( , ) , from , with the same meanings. is a period in European history marking the transition from the Middle Ages to modernity and covering the 15th and 16th centuries, characterized by an effort to revive and surpass ideas ...

that the results found in ''On the Equilibrium of Planes'' began to spread widely. Archimedes' mathematical approach to physics, especially, became a model for subsequent scientists such as

Guidobaldo del Monte Guidobaldo del Monte (11 January 1545 – 6 January 1607, var. Guidobaldi or Guido Baldi), Marquis del Monte, was an Italian mathematician, philosopher and astronomer of the 16th century. Biography Del Monte was born in Pesaro. His father, ...

Bernardino Baldi Bernardino Baldi (5 June 1553 – 10 October 1617) was an Italian mathematician, poet, translator and priest. Baldi descended from a noble family from Urbino, Marche, where he was born. He pursued his studies at Padua, and is said to have spoken ...

Simon Stevin Simon Stevin (; 1548–1620), sometimes called Stevinus, was a Flemish mathematician, scientist and music theorist. He made various contributions in many areas of science and engineering, both theoretical and practical. He also translated vario ...

, and

Galileo Galilei Galileo di Vincenzo Bonaiuti de' Galilei (15 February 1564 – 8 January 1642) was an Italian astronomer, physicist and engineer, sometimes described as a polymath. Commonly referred to as Galileo, his name was pronounced (, ). He was ...

. The concept of centre of gravity reached a high level of sophistication in the second half of the seventeenth century, particularly in the works of

Evangelista Torricelli Evangelista Torricelli ( , also , ; 15 October 160825 October 1647) was an Italian physicist and mathematician, and a student of Galileo. He is best known for his invention of the barometer, but is also known for his advances in optics and work o ...

and

Christiaan Huygens Christiaan Huygens, Lord of Zeelhem, ( , , ; also spelled Huyghens; la, Hugenius; 14 April 1629 – 8 July 1695) was a Dutch mathematician, physicist, engineer, astronomer, and inventor, who is regarded as one of the greatest scientists ...

, and played a pivotal role in the development of rational mechanics.

Criticism

A number of researchers have highlighted inconsistencies within the first book of ''On the Equilibrium of Planes''. Republished translation of the 1883 original by Thomas J. McCormack. Ed. 3, rev. Berggren questions the validity of much of book one, noting for instance the redundancy of Propositions 1-3 and 11-12. However, he follows Dijksterhuis in rejecting Mach's criticism of Proposition 6, suggesting instead that "if a system of weights suspended on a balance beam is in equilibrium when supported at a particular point, then any redistribution of these weights, that preserves their common centre of gravity, also preserves the equilibrium." Additionally, Proposition 7 of book one appears incomplete in its current form, so that strictly speaking Archimedes in the first book demonstrates the

for commensurable magnitudes only. The second book of ''On the Equilibrium of Planes'' is not impacted by these shortcomings because, with the exception of the first proposition, the lever is not treated at all. There is also no definition of the centre of gravity anywhere in Archimedes' extant works, which some scholars argue makes it difficult to follow (or justify) the logical structure of some of his arguments in ''On the Equilibrium of Planes''.

References