Video lesson 2: Pyramid challenge. Pyramid Volume

Video lesson 3: Pyramid challenge. Correct pyramid

Lecture: Pyramid, its base, lateral edges, height, lateral surface; triangular pyramid; right pyramid

Pyramid, its properties

Pyramid- This is a three-dimensional body that has a polygon at the base, and all its faces consist of triangles.

A special case of a pyramid is a cone, at the base of which lies a circle.

Consider the main elements of the pyramid:

Apothem is a segment that connects the top of the pyramid with the middle of the lower edge of the side face. In other words, this is the height of the face of the pyramid.

In the figure you can see the triangles ADS, ABS, BCS, CDS. If you look closely at the names, you can see that each triangle has one common letter in its name - S. That is, this means that all side faces (triangles) converge at one point, which is called the top of the pyramid.

The segment OS, which connects the vertex with the point of intersection of the diagonals of the base (in the case of triangles, at the point of intersection of the heights), is called pyramid height.

A diagonal section is a plane that passes through the top of the pyramid, as well as one of the diagonals of the base.

Since the lateral surface of the pyramid consists of triangles, to find the total area of ​​the lateral surface, it is necessary to find the areas of each face and add them. The number and shape of the faces depends on the shape and size of the sides of the polygon that lies at the base.

The only plane in a pyramid that does not have a vertex is called basis pyramids.

In the figure, we see that the base is a parallelogram, however, there can be any arbitrary polygon.

Properties:

Consider the first case of a pyramid, in which it has edges of the same length:

• A circle can be described around the base of such a pyramid. If you project the top of such a pyramid, then its projection will be located in the center of the circle.
• The angles at the base of the pyramid are the same for each face.
• At the same time, a sufficient condition for the fact that a circle can be described around the base of the pyramid, and also that all the edges are of different lengths, can be considered the same angles between the base and each edge of the faces.

If you come across a pyramid in which the angles between the side faces and the base are equal, then the following properties are true:

• You will be able to describe a circle around the base of the pyramid, the top of which is projected exactly to the center.
• If you draw at each side face of the height to the base, then they will be of equal length.
• To find the lateral surface area of ​​such a pyramid, it is enough to find the perimeter of the base and multiply it by half the length of the height.
• Sbp \u003d 0.5P oc H.
• Types of pyramid.
• Depending on which polygon lies at the base of the pyramid, they can be triangular, quadrangular, etc. If a regular polygon (with equal sides) lies at the base of the pyramid, then such a pyramid will be called regular.

Regular triangular pyramid

Pyramid Concept

Definition 1

A geometric figure formed by a polygon and a point that does not lie in the plane containing this polygon, connected to all the vertices of the polygon, is called a pyramid (Fig. 1).

The polygon from which the pyramid is composed is called the base of the pyramid, the triangles obtained by connecting with the point are the side faces of the pyramid, the sides of the triangles are the sides of the pyramid, and the point common to all triangles is the top of the pyramid.

Types of pyramids

Depending on the number of corners at the base of the pyramid, it can be called triangular, quadrangular, and so on (Fig. 2).

Figure 2.

Another type of pyramid is a regular pyramid.

Let us introduce and prove the property of a regular pyramid.

Theorem 1

All side faces of a regular pyramid are isosceles triangles that are equal to each other.

Proof.

Consider a regular $n-$gonal pyramid with vertex $S$ of height $h=SO$. Let's describe a circle around the base (Fig. 4).

Figure 4

Consider triangle $SOA$. By the Pythagorean theorem, we get

Obviously, any side edge will be defined in this way. Therefore, all side edges are equal to each other, that is, all side faces are isosceles triangles. Let us prove that they are equal to each other. Since the base is a regular polygon, the bases of all side faces are equal to each other. Consequently, all side faces are equal according to the III sign of equality of triangles.

The theorem has been proven.

We now introduce the following definition related to the concept of a regular pyramid.

Definition 3

The apothem of a regular pyramid is the height of its side face.

Obviously, by Theorem 1, all apothems are equal.

Theorem 2

The lateral surface area of ​​a regular pyramid is defined as the product of the semi-perimeter of the base and the apothem.

Proof.

Let us denote the side of the base of the $n-$coal pyramid as $a$, and the apothem as $d$. Therefore, the area of ​​the side face is equal to

Since, by Theorem 1, all sides are equal, then

The theorem has been proven.

Another type of pyramid is the truncated pyramid.

Definition 4

If a plane parallel to its base is drawn through an ordinary pyramid, then the figure formed between this plane and the plane of the base is called a truncated pyramid (Fig. 5).

Figure 5. Truncated pyramid

The lateral faces of the truncated pyramid are trapezoids.

Theorem 3

The area of ​​the lateral surface of a regular truncated pyramid is defined as the product of the sum of the semiperimeters of the bases and the apothem.

Proof.

Let us denote the sides of the bases of the $n-$coal pyramid by $a\ and\ b$, respectively, and the apothem by $d$. Therefore, the area of ​​the side face is equal to

Since all sides are equal, then

The theorem has been proven.

Task example

Example 1

Find the area of ​​the lateral surface of a truncated triangular pyramid if it is obtained from a regular pyramid with base side 4 and apothem 5 by cutting off by a plane passing through the midline of the lateral faces.

Solution.

According to the median line theorem, we obtain that the upper base of the truncated pyramid is equal to $4\cdot \frac(1)(2)=2$, and the apothem is equal to $5\cdot \frac(1)(2)=2.5$.

Then, by Theorem 3, we obtain

Here are collected basic information about the pyramids and related formulas and concepts. All of them are studied with a tutor in mathematics in preparation for the exam.

Consider a plane, a polygon lying in it and a point S not lying in it. Connect S to all vertices of the polygon. The resulting polyhedron is called a pyramid. The segments are called lateral edges. The polygon is called the base, and the point S is called the top of the pyramid. Depending on the number n, the pyramid is called triangular (n=3), quadrangular (n=4), pentagonal (n=5) and so on. Alternative name for the triangular pyramid - tetrahedron. The height of a pyramid is the perpendicular drawn from its apex to the base plane.

A pyramid is called correct if a regular polygon, and the base of the height of the pyramid (the base of the perpendicular) is its center.

Tutor's comment:
Do not confuse the concept of "regular pyramid" and "regular tetrahedron". In a regular pyramid, the side edges are not necessarily equal to the edges of the base, but in a regular tetrahedron, all 6 edges of the edges are equal. This is his definition. It is easy to prove that the equality implies that the center P of the polygon with a height base, so a regular tetrahedron is a regular pyramid.

What is an apothem?
The apothem of a pyramid is the height of its side face. If the pyramid is regular, then all its apothems are equal. The reverse is not true.

Mathematics tutor about his terminology: work with pyramids is 80% built through two types of triangles:
1) Containing apothem SK and height SP
2) Containing the lateral edge SA and its projection PA

To simplify references to these triangles, it is more convenient for a math tutor to name the first of them apothemic, and second costal. Unfortunately, you will not find this terminology in any of the textbooks, and the teacher has to introduce it unilaterally.

Pyramid volume formula:
1) , where is the area of ​​the base of the pyramid, and is the height of the pyramid
2) , where is the radius of the inscribed sphere, and is the total surface area of ​​the pyramid.
3) , where MN is the distance of any two crossing edges, and is the area of ​​the parallelogram formed by the midpoints of the four remaining edges.

Pyramid Height Base Property:

Point P (see figure) coincides with the center of the inscribed circle at the base of the pyramid if one of the following conditions is met:
1) All apothems are equal
2) All side faces are equally inclined towards the base
3) All apothems are equally inclined to the height of the pyramid
4) The height of the pyramid is equally inclined to all side faces

Math tutor's commentary: note that all points are united by one common property: one way or another, side faces participate everywhere (apothems are their elements). Therefore, the tutor can offer a less precise, but more convenient formulation for memorization: the point P coincides with the center of the inscribed circle, the base of the pyramid, if there is any equal information about its lateral faces. To prove it, it suffices to show that all apothemical triangles are equal.

The point P coincides with the center of the circumscribed circle near the base of the pyramid, if one of the three conditions is true:
1) All side edges are equal
2) All side ribs are equally inclined towards the base
3) All side ribs are equally inclined to the height

Introduction

When we began to study stereometric figures, we touched on the topic "Pyramid". We liked this theme because the pyramid is very often used in architecture. And since our future profession as an architect, inspired by this figure, we think that she will be able to push us to great projects.

The strength of architectural structures, their most important quality. Associating strength, firstly, with the materials from which they are created, and, secondly, with the features of design solutions, it turns out that the strength of a structure is directly related to the geometric shape that is basic for it.

In other words, we are talking about the geometric figure that can be considered as a model of the corresponding architectural form. It turns out that the geometric shape also determines the strength of the architectural structure.

The Egyptian pyramids have long been considered the most durable architectural structure. As you know, they have the shape of regular quadrangular pyramids.

It is this geometric shape that provides the greatest stability due to the large base area. On the other hand, the shape of the pyramid ensures that the mass decreases as the height above the ground increases. It is these two properties that make the pyramid stable, and therefore strong in the conditions of gravity.

Objective of the project: learn something new about the pyramids, deepen knowledge and find practical applications.

To achieve this goal, it was necessary to solve the following tasks:

Learn historical information about the pyramid

Consider the pyramid as a geometric figure

Find application in life and architecture

Find similarities and differences between pyramids located in different parts of the world

Theoretical part

Historical information

The beginning of the geometry of the pyramid was laid in ancient Egypt and Babylon, but it was actively developed in ancient Greece. The first to establish what the volume of the pyramid is equal to was Democritus, and Eudoxus of Cnidus proved it. The ancient Greek mathematician Euclid systematized knowledge about the pyramid in the XII volume of his "Beginnings", and also brought out the first definition of the pyramid: a bodily figure bounded by planes that converge from one plane at one point.

The tombs of the Egyptian pharaohs. The largest of them - the pyramids of Cheops, Khafre and Mikerin in El Giza in ancient times were considered one of the Seven Wonders of the World. The erection of the pyramid, in which the Greeks and Romans already saw a monument to the unprecedented pride of kings and cruelty, which doomed the entire people of Egypt to senseless construction, was the most important cult act and was supposed to express, apparently, the mystical identity of the country and its ruler. The population of the country worked on the construction of the tomb in the part of the year free from agricultural work. A number of texts testify to the attention and care that the kings themselves (albeit of a later time) paid to the construction of their tomb and its builders. It is also known about the special cult honors that turned out to be the pyramid itself.

Basic concepts

Pyramid A polyhedron is called, the base of which is a polygon, and the remaining faces are triangles having a common vertex.

Apothem- the height of the side face of a regular pyramid, drawn from its top;

Side faces- triangles converging at the top;

Side ribs- common sides of the side faces;

top of the pyramid- a point connecting the side edges and not lying in the plane of the base;

Height- a segment of a perpendicular drawn through the top of the pyramid to the plane of its base (the ends of this segment are the top of the pyramid and the base of the perpendicular);

Diagonal section of a pyramid- section of the pyramid passing through the top and the diagonal of the base;

Base- a polygon that does not belong to the top of the pyramid.

The main properties of the correct pyramid

Side edges, side faces and apothems are equal, respectively.

The dihedral angles at the base are equal.

The dihedral angles at the side edges are equal.

Each height point is equidistant from all base vertices.

Each height point is equidistant from all side faces.

Basic pyramid formulas

The area of ​​the lateral and full surface of the pyramid.

The area of ​​the lateral surface of the pyramid (full and truncated) is the sum of the areas of all its lateral faces, the total surface area is the sum of the areas of all its faces.

Theorem: The area of ​​the lateral surface of a regular pyramid is equal to half the product of the perimeter of the base and the apothem of the pyramid.

p- perimeter of the base;

h- apothem.

The area of ​​the lateral and full surfaces of a truncated pyramid.

p1, p 2 - base perimeters;

h- apothem.

R- total surface area of ​​a regular truncated pyramid;

S side- area of ​​the lateral surface of a regular truncated pyramid;

S1 + S2- base area

Pyramid Volume

Form The volume scale is used for pyramids of any kind.

H is the height of the pyramid.

Angles of the pyramid

The angles that are formed by the side face and the base of the pyramid are called dihedral angles at the base of the pyramid.

A dihedral angle is formed by two perpendiculars.

To determine this angle, you often need to use the three perpendiculars theorem.

The angles that are formed by a side edge and its projection onto the plane of the base are called angles between the lateral edge and the plane of the base.

The angle formed by two side faces is called dihedral angle at the lateral edge of the pyramid.

The angle, which is formed by two side edges of one face of the pyramid, is called corner at the top of the pyramid.

Sections of the pyramid

The surface of a pyramid is the surface of a polyhedron. Each of its faces is a plane, so the section of the pyramid given by the secant plane is a broken line consisting of separate straight lines.

Diagonal section

The section of a pyramid by a plane passing through two lateral edges that do not lie on the same face is called diagonal section pyramids.

Parallel sections

Theorem:

If the pyramid is crossed by a plane parallel to the base, then the side edges and heights of the pyramid are divided by this plane into proportional parts;

The section of this plane is a polygon similar to the base;

The areas of the section and the base are related to each other as the squares of their distances from the top.

Types of pyramid

Correct pyramid- a pyramid, the base of which is a regular polygon, and the top of the pyramid is projected into the center of the base.

At the correct pyramid:

1. side ribs are equal

2. side faces are equal

3. apothems are equal

4. dihedral angles at the base are equal

5. dihedral angles at side edges are equal

6. each height point is equidistant from all base vertices

7. each height point is equidistant from all side faces

Truncated pyramid- the part of the pyramid enclosed between its base and a cutting plane parallel to the base.

The base and corresponding section of a truncated pyramid are called bases of a truncated pyramid.

A perpendicular drawn from any point of one base to the plane of another is called the height of the truncated pyramid.

Tasks

No. 1. In a regular quadrangular pyramid, point O is the center of the base, SO=8 cm, BD=30 cm. Find the side edge SA.

Problem solving

No. 1. In a regular pyramid, all faces and edges are equal.

Let's consider OSB: OSB-rectangular rectangle, because.

SB 2 \u003d SO 2 + OB 2

SB2=64+225=289

Pyramid in architecture

Pyramid - a monumental structure in the form of an ordinary regular geometric pyramid, in which the sides converge at one point. According to the functional purpose, the pyramids in ancient times were a place of burial or worship. The base of a pyramid can be triangular, quadrangular, or polygonal with an arbitrary number of vertices, but the most common version is the quadrangular base.

A considerable number of pyramids are known, built by different cultures of the Ancient World, mainly as temples or monuments. The largest pyramids are the Egyptian pyramids.

All over the Earth you can see architectural structures in the form of pyramids. Pyramid buildings are reminiscent of ancient times and look very beautiful.

The Egyptian pyramids are the greatest architectural monuments of Ancient Egypt, among which one of the "Seven Wonders of the World" is the pyramid of Cheops. From the foot to the top, it reaches 137.3 m, and before it lost the top, its height was 146.7 m.

The building of the radio station in the capital of Slovakia, resembling an inverted pyramid, was built in 1983. In addition to offices and service premises, there is a fairly spacious concert hall inside the volume, which has one of the largest organs in Slovakia.

The Louvre, which "is as silent and majestic as a pyramid" has undergone many changes over the centuries before becoming the greatest museum in the world. It was born as a fortress, erected by Philip Augustus in 1190, which soon turned into a royal residence. In 1793 the palace became a museum. Collections are enriched through bequests or purchases.

Hypothesis: we believe that the perfection of the shape of the pyramid is due to the mathematical laws embedded in its shape.

Target: having studied the pyramid as a geometric body, to explain the perfection of its form.

Tasks:

1. Give a mathematical definition of a pyramid.

2. Study the pyramid as a geometric body.

3. Understand what mathematical knowledge the Egyptians laid in their pyramids.

Private questions:

1. What is a pyramid as a geometric body?

2. How can the unique shape of the pyramid be explained mathematically?

3. What explains the geometric wonders of the pyramid?

4. What explains the perfection of the shape of the pyramid?

Definition of a pyramid.

PYRAMID (from Greek pyramis, genus n. pyramidos) - a polyhedron, the base of which is a polygon, and the remaining faces are triangles with a common vertex (figure). According to the number of corners of the base, pyramids are triangular, quadrangular, etc.

PYRAMID - a monumental structure that has the geometric shape of a pyramid (sometimes also stepped or tower-shaped). Giant tombs of the ancient Egyptian pharaohs of the 3rd-2nd millennium BC are called pyramids. e., as well as ancient American pedestals of temples (in Mexico, Guatemala, Honduras, Peru) associated with cosmological cults.

It is possible that the Greek word "pyramid" comes from the Egyptian expression per-em-us, that is, from a term that meant the height of the pyramid. The prominent Russian Egyptologist V. Struve believed that the Greek “puram…j” comes from the ancient Egyptian “p"-mr”.

From the history. Having studied the material in the textbook "Geometry" by the authors of Atanasyan. Butuzova and others, we learned that: A polyhedron composed of n-gon A1A2A3 ... An and n triangles RA1A2, RA2A3, ..., RAnA1 is called a pyramid. The polygon A1A2A3 ... An is the base of the pyramid, and the triangles RA1A2, RA2A3, ..., PAnA1 are the lateral faces of the pyramid, P is the top of the pyramid, the segments RA1, RA2, ..., RAn are the lateral edges.

However, such a definition of the pyramid did not always exist. For example, the ancient Greek mathematician, the author of theoretical treatises on mathematics that have come down to us, Euclid, defines a pyramid as a solid figure bounded by planes that converge from one plane to one point.

But this definition has been criticized already in antiquity. So Heron proposed the following definition of a pyramid: “This is a figure bounded by triangles converging at one point and the base of which is a polygon.”

Our group, comparing these definitions, came to the conclusion that they do not have a clear formulation of the concept of “foundation”.

We studied these definitions and found the definition of Adrien Marie Legendre, who in 1794 in his work “Elements of Geometry” defines the pyramid as follows: “Pyramid is a bodily figure formed by triangles converging at one point and ending on different sides of a flat base.”

It seems to us that the last definition gives a clear idea of ​​\u200b\u200bthe pyramid, since it refers to the fact that the base is flat. Another definition of a pyramid appeared in a 19th century textbook: “a pyramid is a solid angle intersected by a plane.”

Pyramid as a geometric body.

That. A pyramid is a polyhedron, one of whose faces (base) is a polygon, the remaining faces (sides) are triangles that have one common vertex (the top of the pyramid).

The perpendicular drawn from the top of the pyramid to the plane of the base is called tallh pyramids.

In addition to an arbitrary pyramid, there are right pyramid, at the base of which is a regular polygon and truncated pyramid.

In the figure - the pyramid PABCD, ABCD - its base, PO - height.

Full surface area A pyramid is called the sum of the areas of all its faces.

Sfull = Sside + Sbase, where Sside is the sum of the areas of the side faces.

pyramid volume is found according to the formula:

V=1/3Sbase h, where Sosn. - base area h- height.

The axis of a regular pyramid is a straight line containing its height.
Apothem ST - the height of the side face of a regular pyramid.

The area of ​​the side face of a regular pyramid is expressed as follows: Sside. =1/2P h, where P is the perimeter of the base, h- the height of the side face (the apothem of a regular pyramid). If the pyramid is crossed by plane A'B'C'D' parallel to the base, then:

1) side edges and height are divided by this plane into proportional parts;

2) in the section, a polygon A'B'C'D' is obtained, similar to the base;

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The bases of the truncated pyramid are similar polygons ABCD and A`B`C`D`, side faces are trapezoids.

Height truncated pyramid - the distance between the bases.

Truncated volume pyramid is found by the formula:

V=1/3 h(S + https://pandia.ru/text/78/390/images/image019_2.png" align="left" width="91" height="96"> The lateral surface area of ​​a regular truncated pyramid is expressed as follows: Sside. = ½(P+P') h, where P and P’ are the perimeters of the bases, h- the height of the side face (the apothem of a regular truncated by feasts

Sections of the pyramid.

Sections of the pyramid by planes passing through its top are triangles.

The section passing through two non-adjacent lateral edges of the pyramid is called diagonal section.

If the section passes through a point on the side edge and the side of the base, then this side will be its trace on the plane of the base of the pyramid.

A section passing through a point lying on the face of the pyramid, and a given trace of the section on the plane of the base, then the construction should be carried out as follows:

find the intersection point of the plane of the given face and the trace of the pyramid section and designate it;

build a straight line passing through a given point and the resulting intersection point;

· Repeat these steps for the next faces.

, which corresponds to the ratio of the legs of a right triangle 4:3. This ratio of the legs corresponds to the well-known right triangle with sides 3:4:5, which is called the "perfect", "sacred" or "Egyptian" triangle. According to historians, the "Egyptian" triangle was given a magical meaning. Plutarch wrote that the Egyptians compared the nature of the universe to a "sacred" triangle; they symbolically likened the vertical leg to the husband, the base to the wife, and the hypotenuse to what is born from both.

For a triangle 3:4:5, the equality is true: 32 + 42 = 52, which expresses the Pythagorean theorem. Is it not this theorem that the Egyptian priests wanted to perpetuate by erecting a pyramid on the basis of the triangle 3:4:5? It is difficult to find a better example to illustrate the Pythagorean theorem, which was known to the Egyptians long before its discovery by Pythagoras.

Thus, the ingenious creators of the Egyptian pyramids sought to impress distant descendants with the depth of their knowledge, and they achieved this by choosing as the "main geometric idea" for the pyramid of Cheops - the "golden" right-angled triangle, and for the pyramid of Khafre - the "sacred" or "Egyptian" triangle.

Very often, in their research, scientists use the properties of pyramids with the proportions of the Golden Section.

In the mathematical encyclopedic dictionary, the following definition of the Golden Section is given - this is a harmonic division, division in the extreme and average ratio - division of the segment AB into two parts in such a way that most of its AC is the average proportional between the entire segment AB and its smaller part CB.

Algebraic finding of the Golden section of a segment AB = a reduces to solving the equation a: x = x: (a - x), whence x is approximately equal to 0.62a. The ratio x can be expressed as fractions 2/3, 3/5, 5/8, 8/13, 13/21…= 0.618, where 2, 3, 5, 8, 13, 21 are Fibonacci numbers.

The geometric construction of the Golden Section of the segment AB is carried out as follows: at point B, the perpendicular to AB is restored, the segment BE \u003d 1/2 AB is laid on it, A and E are connected, DE \u003d BE is postponed, and, finally, AC \u003d AD, then the equality AB is fulfilled: CB = 2: 3.

The golden ratio is often used in works of art, architecture, and is found in nature. Vivid examples are the sculpture of Apollo Belvedere, the Parthenon. During the construction of the Parthenon, the ratio of the height of the building to its length was used and this ratio is 0.618. Objects around us also provide examples of the Golden Ratio, for example, the bindings of many books have a width to length ratio close to 0.618. Considering the arrangement of leaves on a common stem of plants, one can notice that between every two pairs of leaves, the third is located in the place of the Golden Ratio (slides). Each of us “wears” the Golden Ratio with us “in our hands” - this is the ratio of the phalanges of the fingers.

Thanks to the discovery of several mathematical papyri, Egyptologists have learned something about the ancient Egyptian systems of calculus and measures. The tasks contained in them were solved by scribes. One of the most famous is the Rhind Mathematical Papyrus. By studying these puzzles, Egyptologists learned how the ancient Egyptians dealt with the various quantities that arose when calculating measures of weight, length, and volume, which often used fractions, as well as how they dealt with angles.

The ancient Egyptians used a method of calculating angles based on the ratio of the height to the base of a right triangle. They expressed any angle in the language of the gradient. The slope gradient was expressed as a ratio of an integer, called "seked". In Mathematics in the Time of the Pharaohs, Richard Pillins explains: “The seked of a regular pyramid is the inclination of any of the four triangular faces to the plane of the base, measured by a nth number of horizontal units per vertical unit of elevation. Thus, this unit of measure is equivalent to our modern cotangent of the angle of inclination. Therefore, the Egyptian word "seked" is related to our modern word "gradient".

The numerical key to the pyramids lies in the ratio of their height to the base. In practical terms, this is the easiest way to make templates needed to constantly check the correct angle of inclination throughout the construction of the pyramid.

Egyptologists would be happy to convince us that each pharaoh was eager to express his individuality, hence the differences in the angles of inclination for each pyramid. But there could be another reason. Perhaps they all wanted to embody different symbolic associations hidden in different proportions. However, the angle of Khafre's pyramid (based on the triangle (3:4:5) appears in the three problems presented by the pyramids in the Rhind Mathematical Papyrus). So this attitude was well known to the ancient Egyptians.

To be fair to Egyptologists who claim that the ancient Egyptians did not know the 3:4:5 triangle, let's say that the length of the hypotenuse 5 was never mentioned. But mathematical problems concerning the pyramids are always solved on the basis of the seked angle - the ratio of the height to the base. Since the length of the hypotenuse was never mentioned, it was concluded that the Egyptians never calculated the length of the third side.

The height-to-base ratios used in the pyramids of Giza were no doubt known to the ancient Egyptians. It is possible that these ratios for each pyramid were chosen arbitrarily. However, this contradicts the importance attached to numerical symbolism in all types of Egyptian fine art. It is very likely that such relationships were of significant importance, since they expressed specific religious ideas. In other words, the whole complex of Giza was subject to a coherent design, designed to reflect some kind of divine theme. This would explain why the designers chose different angles for the three pyramids.

In The Secret of Orion, Bauval and Gilbert presented convincing evidence of the connection of the pyramids of Giza with the constellation of Orion, in particular with the stars of Orion's Belt. The same constellation is present in the myth of Isis and Osiris, and there is reason to consider each pyramid as an image of one of the three main deities - Osiris, Isis and Horus.

MIRACLES "GEOMETRIC".

Among the grandiose pyramids of Egypt, a special place is occupied by Great Pyramid of Pharaoh Cheops (Khufu). Before proceeding to the analysis of the shape and size of the pyramid of Cheops, we should remember what system of measures the Egyptians used. The Egyptians had three units of length: "cubit" (466 mm), equal to seven "palms" (66.5 mm), which, in turn, was equal to four "fingers" (16.6 mm).

Let's analyze the size of the Cheops pyramid (Fig. 2), following the reasoning given in the wonderful book of the Ukrainian scientist Nikolai Vasyutinskiy "Golden Proportion" (1990).

Most researchers agree that the length of the side of the base of the pyramid, for example, GF is equal to L\u003d 233.16 m. This value corresponds almost exactly to 500 "cubits". Full compliance with 500 "cubits" will be if the length of the "cubit" is considered equal to 0.4663 m.

Pyramid Height ( H) is estimated by researchers differently from 146.6 to 148.2 m. And depending on the accepted height of the pyramid, all the ratios of its geometric elements change. What is the reason for the differences in the estimate of the height of the pyramid? The fact is that, strictly speaking, the pyramid of Cheops is truncated. Its upper platform today has a size of approximately 10 ´ 10 m, and a century ago it was 6 ´ 6 m. It is obvious that the top of the pyramid was dismantled, and it does not correspond to the original one.

Estimating the height of the pyramid, it is necessary to take into account such a physical factor as the "draft" of the structure. For a long time, under the influence of colossal pressure (reaching 500 tons per 1 m2 of the lower surface), the height of the pyramid decreased compared to its original height.

What was the original height of the pyramid? This height can be recreated if you find the basic "geometric idea" of the pyramid.

Figure 2.

In 1837, the English colonel G. Wise measured the angle of inclination of the faces of the pyramid: it turned out to be equal to a= 51°51". This value is still recognized by most researchers today. The indicated value of the angle corresponds to the tangent (tg a), equal to 1.27306. This value corresponds to the ratio of the height of the pyramid AC to half of its base CB(Fig.2), i.e. AC / CB = H / (L / 2) = 2H / L.

And here the researchers were in for a big surprise!.png" width="25" height="24">= 1.272. Comparing this value with the tg value a= 1.27306, we see that these values ​​are very close to each other. If we take the angle a\u003d 51 ° 50", that is, to reduce it by only one arc minute, then the value a will become equal to 1.272, that is, it will coincide with the value of . It should be noted that in 1840 G. Wise repeated his measurements and clarified that the value of the angle a=51°50".

These measurements led researchers to the following very interesting hypothesis: the triangle ASV of the pyramid of Cheops was based on the relation AC / CB = = 1,272!

Consider now a right triangle ABC, in which the ratio of legs AC / CB= (Fig.2). If now the lengths of the sides of the rectangle ABC denote by x, y, z, and also take into account that the ratio y/x= , then, in accordance with the Pythagorean theorem, the length z can be calculated by the formula:

If accept x = 1, y= https://pandia.ru/text/78/390/images/image027_1.png" width="143" height="27">

Figure 3"Golden" right triangle.

A right triangle in which the sides are related as t:golden" right triangle.

Then, if we take as a basis the hypothesis that the main "geometric idea" of the Cheops pyramid is the "golden" right-angled triangle, then from here it is easy to calculate the "design" height of the Cheops pyramid. It is equal to:

H \u003d (L / 2) ´ \u003d 148.28 m.

Let us now derive some other relations for the pyramid of Cheops, which follow from the "golden" hypothesis. In particular, we find the ratio of the outer area of ​​the pyramid to the area of ​​its base. To do this, we take the length of the leg CB per unit, that is: CB= 1. But then the length of the side of the base of the pyramid GF= 2, and the area of ​​the base EFGH will be equal to SEFGH = 4.

Let us now calculate the area of ​​the side face of the Cheops pyramid SD. Because the height AB triangle AEF is equal to t, then the area of ​​the side face will be equal to SD = t. Then the total area of ​​all four side faces of the pyramid will be equal to 4 t, and the ratio of the total external area of ​​the pyramid to the base area will be equal to the golden ratio! That's what it is - the main geometric secret of the pyramid of Cheops!

The group of "geometric wonders" of the pyramid of Cheops includes the real and contrived properties of the relationship between the various dimensions in the pyramid.

As a rule, they are obtained in search of some "constant", in particular, the number "pi" (Ludolf number), equal to 3.14159...; bases of natural logarithms "e" (Napier's number) equal to 2.71828...; the number "F", the number of the "golden section", equal, for example, 0.618 ... etc..

You can name, for example: 1) Property of Herodotus: (Height) 2 \u003d 0.5 st. main x Apothem; 2) Property of V. Price: Height: 0.5 st. osn \u003d Square root of "Ф"; 3) Property of M. Eist: Perimeter of the base: 2 Height = "Pi"; in a different interpretation - 2 tbsp. main : Height = "Pi"; 4) G. Reber's property: Radius of the inscribed circle: 0.5 st. main = "F"; 5) Property of K. Kleppish: (St. main) 2: 2 (st. main x Apothem) \u003d (st. main. U. Apothem) \u003d 2 (st. main x Apothem): ((2 st. main X Apothem) + (st. main) 2). Etc. You can come up with a lot of such properties, especially if you connect two adjacent pyramids. For example, as "Properties of A. Arefiev" it can be mentioned that the difference between the volumes of the pyramid of Cheops and the pyramid of Khafre is equal to twice the volume of the pyramid of Menkaure...

Many interesting provisions, in particular, on the construction of pyramids according to the "golden section" are set out in the books of D. Hambidge "Dynamic Symmetry in Architecture" and M. Geek "Aesthetics of Proportion in Nature and Art". Recall that the "golden section" is the division of the segment in such a ratio, when part A is as many times greater than part B, how many times A is less than the entire segment A + B. The ratio A / B is equal to the number "Ф" == 1.618. .. The use of the "golden section" is indicated not only in individual pyramids, but in the entire pyramid complex in Giza.

The most curious thing, however, is that one and the same pyramid of Cheops simply "cannot" contain so many wonderful properties. Taking a certain property one by one, you can "adjust" it, but all at once they do not fit - they do not coincide, they contradict each other. Therefore, if, for example, when checking all properties, one and the same side of the base of the pyramid (233 m) is initially taken, then the heights of pyramids with different properties will also be different. In other words, there is a certain "family" of pyramids, outwardly similar to those of Cheops, but corresponding to different properties. Note that there is nothing particularly miraculous in the "geometric" properties - much arises purely automatically, from the properties of the figure itself. A "miracle" should be considered only something obviously impossible for the ancient Egyptians. This includes, in particular, "cosmic" miracles, in which the measurements of the Cheops pyramid or the Giza pyramid complex are compared with some astronomical measurements and "even" numbers are indicated: a million times, a billion times less, and so on. Let's consider some "cosmic" relations.

One of the statements is this: "if we divide the side of the base of the pyramid by the exact length of the year, we get exactly 10 millionth of the earth's axis." Calculate: divide 233 by 365, we get 0.638. The radius of the Earth is 6378 km.

Another statement is actually the opposite of the previous one. F. Noetling pointed out that if you use the "Egyptian elbow" invented by him, then the side of the pyramid will correspond to "the most accurate duration of the solar year, expressed to the nearest billionth of a day" - 365.540.903.777.

P. Smith's statement: "The height of the pyramid is exactly one billionth of the distance from the Earth to the Sun." Although the height of 146.6 m is usually taken, Smith took it as 148.2 m. According to modern radar measurements, the semi-major axis of the earth's orbit is 149.597.870 + 1.6 km. This is the average distance from the Earth to the Sun, but at perihelion it is 5,000,000 kilometers less than at aphelion.

Last curious statement:

"How to explain that the masses of the pyramids of Cheops, Khafre and Menkaure are related to each other, like the masses of the planets Earth, Venus, Mars?" Let's calculate. The masses of the three pyramids are related as: Khafre - 0.835; Cheops - 1,000; Mikerin - 0.0915. The ratios of the masses of the three planets: Venus - 0.815; Land - 1,000; Mars - 0.108.

So, despite the skepticism, let's note the well-known harmony of the construction of statements: 1) the height of the pyramid, as a line "going into space" - corresponds to the distance from the Earth to the Sun; 2) the side of the base of the pyramid closest "to the substrate", that is, to the Earth, is responsible for the earth's radius and earth's circulation; 3) the volumes of the pyramid (read - masses) correspond to the ratio of the masses of the planets closest to the Earth. A similar "cipher" can be traced, for example, in bee language, analyzed by Karl von Frisch. However, we refrain from commenting on this for now.

SHAPE OF THE PYRAMIDS

The famous tetrahedral shape of the pyramids did not appear immediately. The Scythians made burials in the form of earthen hills - mounds. The Egyptians built "hills" of stone - pyramids. This happened for the first time after the unification of Upper and Lower Egypt, in the 28th century BC, when the founder of the III dynasty, Pharaoh Djoser (Zoser), faced the task of strengthening the unity of the country.

And here, according to historians, the "new concept of deification" of the tsar played an important role in strengthening the central power. Although the royal burials were distinguished by greater splendor, they did not differ in principle from the tombs of court nobles, they were the same structures - mastabas. Above the chamber with the sarcophagus containing the mummy, a rectangular hill of small stones was poured, where a small building of large stone blocks was then placed - "mastaba" (in Arabic - "bench"). On the site of the mastaba of his predecessor, Sanakht, Pharaoh Djoser erected the first pyramid. It was stepped and was a visible transitional stage from one architectural form to another, from a mastaba to a pyramid.

In this way, the pharaoh was "raised" by the sage and architect Imhotep, who was later considered a magician and identified by the Greeks with the god Asclepius. It was as if six mastabas were erected in a row. Moreover, the first pyramid occupied an area of ​​1125 x 115 meters, with an estimated height of 66 meters (according to Egyptian measures - 1000 "palms"). At first, the architect planned to build a mastaba, but not oblong, but square in plan. Later it was expanded, but since the extension was made lower, two steps were formed, as it were.

This situation did not satisfy the architect, and on the top platform of a huge flat mastaba, Imhotep placed three more, gradually decreasing towards the top. The tomb was under the pyramid.

Several more stepped pyramids are known, but later the builders moved on to building more familiar tetrahedral pyramids. Why, however, not triangular or, say, octagonal? An indirect answer is given by the fact that almost all the pyramids are perfectly oriented to the four cardinal points, and therefore have four sides. In addition, the pyramid was a "house", a shell of a quadrangular burial chamber.

But what caused the angle of inclination of the faces? In the book "The Principle of Proportions" a whole chapter is devoted to this: "What could determine the angles of the pyramids." In particular, it is indicated that "the image to which the great pyramids of the Old Kingdom gravitate is a triangle with a right angle at the top.

In space, it is a semi-octahedron: a pyramid in which the edges and sides of the base are equal, the faces are equilateral triangles. Certain considerations are given on this subject in the books of Hambidge, Geek and others.

What is the advantage of the angle of the semioctahedron? According to the descriptions of archaeologists and historians, some pyramids collapsed under their own weight. What was needed was a "durability angle", an angle that was the most energetically reliable. Purely empirically, this angle can be taken from the vertex angle in a pile of crumbling dry sand. But to get accurate data, you need to use the model. Taking four firmly fixed balls, you need to put the fifth one on them and measure the angles of inclination. However, here you can make a mistake, therefore, a theoretical calculation helps out: you should connect the centers of the balls with lines (mentally). At the base, you get a square with a side equal to twice the radius. The square will be just the base of the pyramid, the length of the edges of which will also be equal to twice the radius.

Thus a dense packing of balls of the 1:4 type will give us a regular semi-octahedron.

However, why do many pyramids, gravitating towards a similar form, nevertheless do not retain it? Probably the pyramids are getting old. Contrary to the famous saying:

"Everything in the world is afraid of time, and time is afraid of the pyramids", the buildings of the pyramids must age, they can and should take place not only the processes of external weathering, but also the processes of internal "shrinkage", from which the pyramids may become lower. Shrinkage is also possible because, as found out by the works of D. Davidovits, the ancient Egyptians used the technology of making blocks from lime chips, in other words, from "concrete". It is these processes that could explain the reason for the destruction of the Medum pyramid, located 50 km south of Cairo. It is 4600 years old, the dimensions of the base are 146 x 146 m, the height is 118 m. “Why is it so mutilated?” asks V. Zamarovsky. “The usual references to the destructive effects of time and “the use of stone for other buildings” do not fit here.

After all, most of its blocks and facing slabs still remain in place, in the ruins at its foot. "As we will see, a number of provisions make one think even that the famous pyramid of Cheops also" shrunken ". In any case, on all ancient images, the pyramids are pointed ...

The shape of the pyramids could also be generated by imitation: some natural patterns, "miraculous perfection", say, some crystals in the form of an octahedron.

Such crystals could be diamond and gold crystals. A large number of "intersecting" signs for such concepts as Pharaoh, Sun, Gold, Diamond is characteristic. Everywhere - noble, brilliant (brilliant), great, flawless and so on. The similarities are not accidental.

The solar cult, as you know, was an important part of the religion of ancient Egypt. “No matter how we translate the name of the greatest of the pyramids,” one of the modern textbooks says, “Sky Khufu” or “Sky Khufu”, it meant that the king is the sun. If Khufu, in the brilliance of his power, imagined himself to be a second sun, then his son Jedef-Ra became the first of the Egyptian kings who began to call himself "the son of Ra", that is, the son of the Sun. The sun was symbolized by almost all peoples as "solar metal", gold. "The big disk of bright gold" - so the Egyptians called our daylight. The Egyptians knew gold very well, they knew its native forms, where gold crystals can appear in the form of octahedrons.

As a "sample of forms" the "sun stone" - a diamond - is also interesting here. The name of the diamond came just from the Arab world, "almas" - the hardest, hardest, indestructible. The ancient Egyptians knew the diamond and its properties are quite good. According to some authors, they even used bronze pipes with diamond cutters for drilling.

South Africa is now the main supplier of diamonds, but West Africa is also rich in diamonds. The territory of the Republic of Mali is even called the "Diamond Land" there. Meanwhile, it is on the territory of Mali that the Dogon live, with whom the supporters of the paleovisit hypothesis pin many hopes (see below). Diamonds could not be the reason for the contacts of the ancient Egyptians with this region. However, one way or another, it is possible that it was precisely by copying the octahedrons of diamond and gold crystals that the ancient Egyptians deified the pharaohs, “indestructible” like diamond and “brilliant” like gold, the sons of the Sun, comparable only with the most wonderful creations of nature.

Conclusion:

Having studied the pyramid as a geometric body, getting acquainted with its elements and properties, we were convinced of the validity of the opinion about the beauty of the shape of the pyramid.

As a result of our research, we came to the conclusion that the Egyptians, having collected the most valuable mathematical knowledge, embodied it in a pyramid. Therefore, the pyramid is truly the most perfect creation of nature and man.

BIBLIOGRAPHY

"Geometry: Proc. for 7 - 9 cells. general education institutions \, etc. - 9th ed. - M .: Education, 1999

History of mathematics at school, M: "Enlightenment", 1982

Geometry grade 10-11, M: "Enlightenment", 2000

Peter Tompkins "Secrets of the Great Pyramid of Cheops", M: "Centropoligraph", 2005

Internet resources

http://veka-i-mig. *****/

http://tambov. *****/vjpusk/vjp025/rabot/33/index2.htm

http://www. *****/enc/54373.html