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Intercept theorem

The Intercept theorem, also known as Thales's theorem or the basic proportionality theorem, states that a straight line drawn parallel to one side of a triangle intersects the other two sides proportionally, dividing them into segments such that the ratios of the corresponding segments are equal; conversely, if a straight line intersects two sides of a triangle proportionally, it is parallel to the third side.^[1] This theorem forms a foundational result in Euclidean geometry, enabling the establishment of similarity between triangles through proportional divisions.^[2] Attributed to the ancient Greek mathematician Thales of Miletus (c. 624–546 BCE), the theorem is said to have been used by Thales to measure the height of Egyptian pyramids by comparing shadows cast by the pyramids to those of nearby sticks at midday, leveraging proportional similarities.^[3] Although Thales likely discovered intuitive applications, the theorem was rigorously formalized by Euclid in his Elements (Book VI, Proposition 2), where the proof relies on constructing similar triangles and applying properties of parallel lines and equal alternate angles.^[1] In its general form, known as the transversal intercept theorem, it extends to cases where multiple parallel lines intersect two transversals, dividing them into proportional segments, which holds under signed ratios for interior and exterior intersections.^[3] The theorem's proof in Euclid's framework demonstrates proportionality by showing that triangles formed by the parallel line and the triangle's vertex are similar, with corresponding sides in the same ratio due to equal angles.^[1] It underpins key concepts in plane geometry, such as the properties of similar figures and the angle bisector theorem, and is a result specific to Euclidean geometry.^[2] Applications include solving problems in architecture, engineering, and computer graphics for scaling and proportioning figures, as well as in educational contexts for introducing proportionality and parallel line properties.

Formulation and Basic Concepts

Statement of the Theorem

The intercept theorem, also known as the basic proportionality theorem, is a key result in Euclidean geometry stating that if a straight line parallel to one side of a triangle intersects the other two sides, then it divides those sides into proportional segments.^[4] Specifically, consider triangle \triangle ABC with a line DE parallel to side BC, where D lies on side AB and E lies on side AC. The theorem asserts that

\frac{AD}{DB} = \frac{AE}{EC}.

This holds under the conditions that the figure is in the Euclidean plane, the transversals AB and AC are straight lines intersecting at vertex A, and DE is strictly parallel to BC.^[4] The theorem also includes its converse: if a line intersects the two sides of a triangle such that it divides them into proportional segments, then that line is parallel to the third side.^[4] This proportionality can be visualized in a diagram where \triangle ABC has base BC, and the parallel line DE creates a smaller triangle \triangle ADE similar to \triangle ABC, dividing the sides proportionally from the vertex (as detailed in related concepts on triangle similarity). The result generalizes beyond triangles to the case of two straight transversals cut by parallel lines, where the parallel lines divide the transversals into proportional segments.^[5] For instance, if transversals AB and CD are intersected by parallel lines at points P and Q on AB, and corresponding points R and S on CD, then the ratios of the segments satisfy \frac{AP}{PQ} = \frac{CR}{RS} (and similarly for other corresponding parts), assuming at least three parallel lines for the full proportionality among multiple segments.^[5] The conditions require the transversals to be straight, the intersecting lines to be parallel, and the configuration to lie in a plane.^[5]

Geometric Configuration

The intercept theorem, also known as the basic proportionality theorem, involves a geometric configuration where a set of two or more parallel lines intersects a pair of non-parallel transversals, resulting in the transversals being divided into proportional segments by the points of intersection.^[6] In this setup, the parallel lines act as "cutters," and the transversals are the lines being segmented; the ratios of the lengths of these segments on one transversal equal the corresponding ratios on the other.^[7] A simple and intuitive example of this configuration appears in a triangle ABC, where a line segment DE parallel to base BC intersects side AB at point D and side AC at point E. This parallel line creates a smaller triangle ADE similar to the original triangle ABC, with the segments on the sides divided proportionally: the ratio \frac{AD}{DB} = \frac{AE}{EC}.^[6] For instance, if AD measures 2 units and DB measures 3 units, then AE must also be to EC as 2 to 3, ensuring the overall division maintains the same ratio along both transversals AB and AC.^[7] This proportionality arises directly from the parallel lines preserving equal angles with the transversals, leading to consistent segment ratios. A common misconception is that such proportional divisions occur with non-parallel lines intersecting the transversals; however, without parallelism, the angles differ, and the segment ratios are not preserved.^[6]

Proofs and Derivations

Proof Using Similar Triangles

Consider a triangle ABC in the Euclidean plane, where a line segment DE is drawn parallel to side BC, with D on side AB and E on side AC. This configuration assumes the Euclidean parallel postulate, which guarantees that parallel lines maintain equal corresponding angles with a transversal. To prove the intercept theorem, observe that \triangle ADE and \triangle ABC share the angle at vertex A, so \angle DAE = \angle BAC. Additionally, since DE \parallel BC, the alternate interior angles formed by transversal AB are equal: \angle ADE = \angle ABC. Similarly, for transversal AC, \angle AED = \angle ACB. Thus, by the AA similarity criterion, \triangle ADE \sim \triangle ABC.^[4]^[8] The similarity implies that corresponding sides are proportional. Here, side AD corresponds to AB, AE to AC, and DE to BC. Therefore,

\frac{AD}{AB} = \frac{AE}{AC} = \frac{DE}{BC}.

This establishes that the parallel line divides the other two sides proportionally, which is the statement of the intercept theorem. No auxiliary lines beyond the parallel segment DE are required for this construction.^[4]

Vector-Based Proof

The vector-based proof of the intercept theorem employs position vectors in a Euclidean plane to demonstrate the proportionality of segments without relying on coordinate systems or synthetic geometry. Consider two transversals intersecting at the origin O, represented by rays along linearly independent vectors \vec{s_1} and \vec{s_2}. The parallel lines intercept these transversals at points A_1 = \lambda \vec{s_1} and A_2 = \mu \vec{s_2} for one parallel, and at B_1 = \nu \vec{s_1} and B_2 = \xi \vec{s_2} for another parallel, where \lambda, \mu, \nu, \xi > 0.^[9] The parallelism of the intercepting lines implies that the vector \vec{A_1A_2} = \mu \vec{s_2} - \lambda \vec{s_1} is a scalar multiple of \vec{B_1B_2} = \xi \vec{s_2} - \nu \vec{s_1}, so \mu \vec{s_2} - \lambda \vec{s_1} = k (\xi \vec{s_2} - \nu \vec{s_1}) for some scalar k > 0. Rearranging yields (-\lambda + k \nu) \vec{s_1} + (\mu - k \xi) \vec{s_2} = \vec{0}. Since \vec{s_1} and \vec{s_2} are linearly independent, their coefficients must vanish: -\lambda + k \nu = 0 and \mu - k \xi = 0, or \lambda / \nu = k = \mu / \xi. Thus, the ratios \lambda / \nu = \mu / \xi, showing that the parallels divide the transversals proportionally.^[9] In the specific case of a triangle, let the vertex be at the origin with position vectors \vec{A} and \vec{B} for the base endpoints. A line parallel to the base intersects the sides at P = (1 - t) \vec{0} + t \vec{A} = t \vec{A} and Q = (1 - t) \vec{0} + t \vec{B} = t \vec{B} for the same parameter t \in (0,1), due to the parallelism condition equating the parametric ratios along each side. This confirms the segments are divided in the ratio t : (1 - t) equally on both sides. This approach highlights the theorem's algebraic elegance, generalizing readily to higher-dimensional spaces where parallel hyperplanes intercept affine subspaces proportionally, though the full derivation follows analogous linear independence arguments.

Historical Context

Origins in Ancient Geometry

The earliest evidence of principles akin to the intercept theorem appears in Babylonian mathematics around 2000 BCE, where clay tablets demonstrate practical applications of proportional divisions in geometric figures, particularly trapezoids. For instance, the tablet YBC 3879 from Ur III Umma (ca. 2046 BCE) describes the division of a trapezoidal field into parallel stripes of equal area, employing quadratic equations and proportional relationships between sides to determine segment lengths, such as calculating partial fronts using a "feed" factor for bisection.^[10] Similarly, Old Babylonian tablets like IM 55357 (ca. 1900–1600 BCE) utilize ratios in similar right-angled triangles within wedge-shaped figures—effectively trapezoidal configurations—to scale lengths and areas recursively, reflecting empirical methods for land measurement without abstract theorems.^[11] In ancient Egypt, around 1650 BCE, the Rhind Mathematical Papyrus illustrates the use of proportional scaling in pyramid construction through the concept of the seked, which measures the slope as a ratio of horizontal run to vertical rise, equivalent to the cotangent and reliant on similar triangles. Problems such as RMP 56, which calculates the seked of a pyramid 250 cubits high with a square base side of 360 cubits (resulting in a seked of 5 1/25 palms), while RMP 58 computes it for a pyramid with height 93⅓ cubits and base 140 cubits, enabling consistent scaling of dimensions across levels.^[12] This approach supported practical engineering, ensuring proportional inclines without formal geometric proofs. Indian texts from the Sulba Sutras (ca. 800–500 BCE) extend these ideas to altar constructions, incorporating proportionality rules derived from similar triangles to maintain geometric harmony. For example, Baudhayana's Sulba Sutra employs ratios in dissecting figures to verify relationships like the Pythagorean theorem, scaling altar components—such as transforming rectangles into squares—through proportional segments that align with intercept-like divisions.^[13] Across these civilizations, applications remained empirical, focused on construction and measurement rather than deductive proofs, laying groundwork later formalized in Greek geometry.

Attribution to Thales

Thales of Miletus, active around 624–546 BCE, is traditionally credited with pioneering the use of proportionality in geometry, exemplified by his method of measuring the heights of Egyptian pyramids using shadows. According to historical accounts, Thales waited for the moment when his own shadow equaled his height, then measured the pyramid's shadow at the same time, applying the principle that the ratios of corresponding sides in similar triangles are equal to deduce the pyramid's height from the known ratio of shadow lengths.^[14]^[15] This application of proportionality underpins the intercept theorem, and its formalization appears in Euclid's Elements, Book VI, Proposition 2, which states that if a straight line parallel to one side of a triangle intersects the other two sides, it divides those sides proportionally. Euclid does not explicitly attribute the result to Thales, but the proposition's content aligns closely with Thales' reported techniques, suggesting an indirect credit through the evolution of Greek geometric thought.^[4] The primary source for attributing the intercept theorem to Thales is Eudemus of Rhodes' History of Geometry (c. 320 BCE), now lost but preserved in fragments quoted by later commentators like Proclus. Eudemus reportedly described Thales' method for determining distances at sea using similar proportionality, extending to the theorem's core idea, though debates persist among historians due to the fragmentary nature of the evidence and potential later embellishments.^[16]^[17] As a foundational result, the intercept theorem influenced the axiomatic structure of geometry by establishing key properties of similarity and proportion, enabling Euclid's systematic development of these concepts in Books VI and beyond without relying on empirical measurement alone.^[18]

Triangle Similarity

Similar triangles are geometric figures that have equal corresponding angles and proportional corresponding sides.^[19] This property ensures that the triangles maintain the same shape, differing only in size, and forms the foundation for many proportionality results in plane geometry.^[20] The criteria for establishing triangle similarity include the AA (angle-angle) criterion, which requires two pairs of corresponding angles to be equal; since the sum of angles in a triangle is 180 degrees, the third angles are automatically equal.^[21] The SAS (side-angle-side) similarity criterion applies when two pairs of corresponding sides are proportional and the included angles are equal.^[21] Finally, the SSS (side-side-side) criterion holds if all three pairs of corresponding sides are proportional, implying equal corresponding angles.^[21] These criteria, derived from foundational Euclidean propositions, allow for the identification of similarity without measuring all elements.^[22] In the intercept theorem, a line parallel to one side of a triangle intersects the other two sides, creating corresponding angles that are equal due to alternate interior angles formed by parallel lines and transversals; this satisfies the AA similarity criterion, resulting in proportional sides between the smaller and larger triangles.^[3] Consequently, the segments intercepted on the sides are divided in the same ratio as the similarity ratio of the triangles.^[21] For example, in \triangle ABC with line DE parallel to base BC, where D lies on AB and E on AC, \triangle ADE \sim \triangle ABC by AA similarity, with similarity ratio k = \frac{AD}{AB} = \frac{AE}{AC}. The intercepted segments AD and AE are thus divided in the ratio k, while DB and EC follow the complementary ratio $1 - k.^[3] This direct application underscores how similarity enforces the proportional divisions central to the intercept theorem.

Homothety and Scaling

Homothety, also known as dilation, is a type of similarity transformation in Euclidean geometry defined by a fixed point O called the center and a scale factor k > 0, which maps any point P to a point P' lying on the ray starting from O through P such that the distance OP' = k \cdot OP.^[23]^[24] This transformation enlarges or reduces figures while preserving their shape, angles, and orientation, with k > 1 indicating enlargement and $0 < k < 1 indicating reduction.^[23] Homotheties map straight lines to parallel straight lines, except for lines passing through the center, which remain invariant as sets.^[24]^[25] In the context of the intercept theorem, homothety provides a transformative perspective on the proportionality of segments intercepted by parallel lines on transversals. The theorem's configuration—where parallel lines are cut by two transversals intersecting at a point—positions that intersection as the center of a homothety that maps one parallel line to the other, scaling the intercepted segments by the fixed ratio k.^[26]^[24] Under this homothety, parallel intercepts maintain their proportional ratios, as corresponding segments on the transversals are uniformly scaled by k, directly embodying the theorem's statement of constant division ratios.^[26] This relation underscores how homothety generalizes the theorem's geometric proportionality to broader similarity contexts. The geometric properties of homothety further illuminate its role in the intercept theorem. The center O serves as the unique fixed point, remaining unchanged under the transformation, while all other points are displaced along rays from O.^[25]^[23] Segments not passing through the center are dilated by the factor k, with their lengths multiplied by |k| and directions preserved if k > 0, ensuring that the parallel structure of the intercepts in the theorem is maintained without distortion.^[24] These properties highlight homothety's utility in explaining the consistent scaling observed in the theorem's proportional divisions.

Proportional Segments in Vectors

In vector spaces, line segments can be represented as convex combinations of position vectors, where a point dividing the segment from \mathbf{A} to \mathbf{B} in the ratio r:1 is given by \mathbf{P} = \frac{r \mathbf{B} + \mathbf{A}}{r+1}. Parallel lines in this context are characterized by direction vectors that are scalar multiples of each other, ensuring that transversals are intercepted in a manner consistent with the intercept theorem. This formulation aligns the geometric intercept condition with algebraic vector operations, where the proportionality arises from the linearity of scalar multiplication.^[27] The theorem extends naturally to affine geometry, where affine combinations preserve ratios along lines under translations and linear transformations. In an affine space, if two parallel affine lines intersect two transversals, the division ratios of the segments remain equal, as affine maps maintain collinearity and parallelism without altering relative proportions. This invariance holds because translations do not affect vector differences, which define the directions and ratios. Consider two transversals defined by lines from a common point, intercepted by parallel lines. For points \mathbf{A}, \mathbf{P} on one transversal and \mathbf{C}, \mathbf{R} on the other, with parallels intersecting at \mathbf{P} and \mathbf{R}, and similarly \mathbf{B}, \mathbf{S} further along, the ratio satisfies

r = \frac{|\mathbf{AP}|}{|\mathbf{PB}|} = \frac{|\mathbf{CR}|}{|\mathbf{RS}|},

where the equality follows from the scalar factor relating the parallel direction vectors.^[27] This vector perspective generalizes the intercept theorem to n-dimensional spaces, where the same proportionality holds for hyperplanes parallel in the affine sense, without requiring a separate proof due to the uniformity of vector space axioms across dimensions.

Extensions and Generalizations

Basic Proportionality Theorem

The Basic Proportionality Theorem, also known as the intercept theorem in its triangle form, encompasses both a direct statement and its converse, establishing key relationships between parallel lines and proportional segments within a triangle. The direct theorem asserts that if a line drawn parallel to one side of a triangle intersects the other two sides, it divides those sides into segments that are proportional. Specifically, for triangle ABC with line DE parallel to side BC, where D lies on AB and E on AC, the ratios satisfy \frac{AD}{DB} = \frac{AE}{EC}.^[4] The converse of the theorem states that if a line intersects two sides of a triangle and divides them into proportional segments, then that line is parallel to the third side. In the same notation, if \frac{AD}{DB} = \frac{AE}{EC}, then DE is parallel to BC. This bidirectional relationship forms the core of the intercept theorem's application in triangular geometry.^[4] A special case arises when the intersecting line joins the midpoints of the two sides, known as the midsegment or midline theorem. Here, the line segment connecting the midpoints of two sides of a triangle is parallel to the third side and exactly half its length. For instance, in triangle ABC, if M and N are midpoints of AB and AC, respectively, then MN is parallel to BC and MN = \frac{1}{2} BC. This follows directly from the proportionality ratios being equal to 1 in the direct theorem.^[28] Proof sketches for the theorem can employ areas or coordinate geometry without full derivation. Using areas, the parallel line creates smaller triangles with the same height relative to the base, implying that their areas are proportional to the bases, which yields the segment ratios. Alternatively, in coordinate geometry, placing vertex A at the origin and sides along axes allows algebraic verification of the ratios under parallelism conditions.^[4]

Applications to Parallel Lines in Polygons

The intercept theorem extends naturally to trapezoids, which are quadrilaterals with exactly one pair of parallel sides known as the bases. When a transversal line is drawn parallel to these bases and intersects the non-parallel sides (legs), it divides each leg into segments that are proportional. Specifically, the ratios of the segments on one leg equal the ratios on the other leg, reflecting the theorem's core principle of proportional division by parallels.^[29] This proportionality in trapezoids can be understood through the correspondence between height ratios and segment proportions. For instance, if the transversal divides the height of the trapezoid in the ratio k:1-k from one base, the segments on the legs will be divided in the same ratio k:1-k, ensuring the transversal's length is a linear interpolation between the base lengths. Such divisions are evident in ancient Elamite mathematical texts, where transversals parallel to trapezoid bases were used to compute proportional lengths and areas.^[30] In more general polygons featuring multiple parallel lines, the intercept theorem generalizes to create proportional bands across the figure. Successive parallel lines intersecting the non-parallel boundaries divide those boundaries into segments whose ratios accumulate proportionally, forming a series of strips where each band's width corresponds to uniform proportional intercepts on the transversals. This application is particularly useful in polygonal decompositions involving parallel rulings, as seen in extensions of Euclidean proportionality to higher-order figures.^[31] A key limitation of these applications is the requirement for at least one pair of parallel lines to establish the proportional framework; without parallels, the theorem does not apply, and segments may not maintain consistent ratios. This constraint underscores the theorem's reliance on parallelism for its geometric invariance.^[30]

Practical Applications

Geometric Constructions

The intercept theorem facilitates compass-and-straightedge constructions for dividing a line segment into proportional parts by leveraging parallel lines to ensure proportional intercepts on transversals. To divide a given segment AB in the ratio m:n, begin by drawing a ray from endpoint A in a direction not collinear with AB. Using the compass, mark off m + n equal arbitrary lengths along this ray, labeling the points sequentially from A to a final point P such that the segment from A to the m-th mark represents the proportion m. Connect P to B with the straightedge, then draw a line parallel to PB through the m-th point on the ray, intersecting AB at the desired division point D. This method relies on the theorem's guarantee that the parallel line divides the transversals proportionally, yielding AD:DB = m:n.^[32] Algebraically, the construction invokes similar triangles formed by the parallel line. Consider the ray as one transversal and AB as the other; the parallel through the m-th point creates triangles similar to the larger one formed by PB, with side ratios equal to m:(m+n) along the ray, ensuring the intercept on AB matches the ratio m:n by the proportionality of corresponding sides in similar triangles. This approach solves the division problem without direct measurement, as the equal marks on the ray can be any convenient length, scalable by the theorem's properties.^[33] For instance, to divide segment AB in the ratio 3:5, mark six equal segments on the ray from A, connect the sixth point to B, and draw the parallel from the third point to intersect AB at D, resulting in AD:DB = 3:5. This exemplifies how the theorem enables precise proportional division through geometric similarity rather than numerical computation.^[32] Historically, the intercept theorem addresses limitations in ruler-and-compass tools by providing a rigorous basis for proportional constructions that avoid unmarked rulers' inability to transfer arbitrary ratios directly, allowing ancient geometers to achieve such divisions solely through parallelism and equality of lengths.^[33]

Surveying Techniques

One practical application of the intercept theorem in surveying involves measuring the width of a river or other inaccessible distances using similar triangles. A surveyor selects a point A on one bank and measures a baseline AB along the bank to point B. From A, a line of sight is drawn across the river to a visible point C on the opposite bank. From B, a line is drawn parallel to AC, intersecting a line extended from B along the direction of the river or another reference to form similar triangles, allowing the width to be calculated proportionally to the known baseline AB using the theorem's ratios.^[34] This technique relies on the theorem's proportionality to avoid direct measurement across the water, providing an efficient field method for land mapping.^[35] For estimating the height of tall objects, such as trees or structures, surveyors employ the shadow method, which leverages similar triangles formed by shadows under parallel sunlight rays, a principle attributed to Thales of Miletus in ancient accounts. According to historical reports, Thales measured the height of Egyptian pyramids by waiting for the moment when his own shadow equaled his height and then comparing it to the pyramid's shadow length, applying the intercept theorem's proportional ratios to deduce the full height without climbing.^[36] This approach remains a foundational indirect measurement technique in basic surveying, adaptable to various vertical assessments using a gnomon or rod.^[37] In modern surveying, theodolites and total stations incorporate the intercept theorem through the stadia method, where artificial parallel lines are created via telescope crosshairs to measure intercepted segments on a staff, enabling distance ratios for horizontal and vertical computations. The instrument's stadia hairs are spaced to form similar triangles with a fixed ratio (typically 1:100), allowing surveyors to calculate distances as D = 100S (where S is the intercepted length) without physical tapes, particularly useful over rough terrain or obstacles.^[38] This tacheometric application enhances precision in large-scale topographic surveys by directly applying proportional intercepts.^[39] A notable historical adaptation appears in Eratosthenes' third-century BCE calculation of Earth's circumference, where he used proportional shadow lengths from parallel solar rays at two locations (Syene and Alexandria) to establish angular differences and arc segments, akin to the intercept theorem's principles for global-scale measurement. By measuring a 7.2-degree angle difference over a known baseline of about 800 kilometers, he scaled the ratio to estimate the full 360-degree circumference at approximately 40,000 kilometers, demonstrating the theorem's extension to spherical geometry.^[40]

Architectural Measurements

In modern architectural design, the intercept theorem supports scaling techniques to ensure proportional facades and elevations, particularly through parallel projections in plans and sections. Architects apply the theorem by treating building edges as transversals intersected by parallel construction lines, verifying that facade elements like windows, columns, and cornices divide sides in consistent ratios for visual and structural harmony. This approach is evident in computational design tools for generating quad meshes on building envelopes, where parallel edges aligned via the intercept theorem produce scalable, proportional patterns that maintain geometric integrity across different building scales.^[41]^[42] The theorem also informs structural engineering applications, such as analyzing bridge trusses with parallel chord members divided by diagonal transversals. In these configurations, proportional intercepts allow engineers to calculate segment lengths and distribute loads evenly, ensuring the truss's overall stability and efficiency without exhaustive computations. This proportional division simplifies dimensioning for parallel frameworks common in bridge designs, where maintaining ratios prevents disproportionate stress concentrations.^[41] Renaissance architects exemplified the theorem's role in verifying dome proportions, as seen in Filippo Brunelleschi's design for the Florence Cathedral dome (completed 1436 CE). Brunelleschi integrated mathematical proportionality to scale ribs, arches, and octagonal sections, ensuring each element aligned in harmonic ratios relative to the base diameter of approximately 45.5 meters. This geometric rigor allowed precise construction of the double-shelled dome without centering scaffolds, balancing aesthetics with load-bearing capacity through verified proportional segments.^[43]

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[35]
(PDF) Eighteenth Century Land Surveying as a Context for Learning ...
The focus was on teaching measurement skills and the application of similar triangles to eight-and ninth-grade students. The profession of the Dutch land ...
[36]
Some Original Sources for Modern Tales of Thales
Hieronymus informs us that he measured the height of the pyramids by the shadow they cast, taking the observation at the hour when our shadow is of the same ...
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Thales' Shadow - jstor
"[Thales]... succeeded in measuring the height of the pyramids by observing the length of the shadow at the moment when a man's shadow is equal to his own.
[38]
https://www.ams.org/publicoutreach/feature-column/fcarc-surveying-one
[39]
Eratosthenes Measures Earth | American Physical Society
Jun 1, 2006 · The first person to determine the size of Earth was Eratosthenes of Cyrene, who produced a surprisingly good measurement using a simple scheme.
[40]
[PDF] THE 3,000 YEAR REIGN OF THE PHARAOHS AND QUEENS OF ...
The Great Pyramid of Giza was built around 2560 BCE, by Khufu during the Fourth. Dynasty. It was one of the 7. Wonders of the Ancient. World. It was built as a ...
[41]
Summary of Applying the Theorem of Thales in Practice - Teachy
The Theorem of Thales has various practical applications in areas such as engineering, architecture, and design. It is used to ensure proportion and accuracy in ...
[42]
[PDF] Computational design and optimization of quad meshes based on ...
By the intercept theorem, its edges are parallel to the diagonals of the ... This chapter will focus on the application of A-Nets in an architectural context.
[43]
[PDF] Brunelleschi and the Dome of the Florentine Cathedral
Brunelleschi believed that each part of a structure had to be mathematically proportional to all other parts of the structure, which was rendered in ratios of ...