Find the area of ​​a parallelogram online calculator. Parallelogram and its properties

A parallelogram is a quadrangular figure whose opposite sides are pairwise parallel and pairwise equal. Its opposite angles are also equal, and the intersection point of the diagonals of the parallelogram divides them in half, while being the center of symmetry of the figure. Special cases of a parallelogram are such geometric shapes as a square, a rectangle and a rhombus. The area of ​​a parallelogram can be found different ways, depending on what initial data is accompanied by the problem statement.

1. In the simplest case, the area of ​​a parallelogram is defined as the product of its base and its height.
   

   S = DC ∙ h

   
   

   where S is the area of ​​the parallelogram;
   a - base;
   h is the height drawn to the given base.

   This formula is very easy to understand and remember if you look at the following figure.

   

   As you can see from this image, if we cut off an imaginary triangle to the left of the parallelogram and attach it to the right, then as a result we get a rectangle. And as you know, the area of ​​a rectangle is found by multiplying its length by its height. Only in the case of a parallelogram, the length will be the base, and the height of the rectangle will be the height of the parallelogram lowered to this side.

2. The area of ​​a parallelogram can also be found by multiplying the lengths of two adjacent bases and the sine of the angle between them:
   

   S = AD∙AB∙sinα

   
   

   where AD, AB are adjacent bases that form the intersection point and the angle a between themselves;
   α is the angle between the bases AD and AB.

   

3. Also, the area of ​​a parallelogram can be found by dividing in half the product of the lengths of the diagonals of the parallelogram by the sine of the angle between them.
   

   S = ½∙AC∙BD∙sinβ

   
   

   where AC, BD are the diagonals of the parallelogram;
   β is the angle between the diagonals.

   

4. There is also a formula for finding the area of ​​a parallelogram in terms of the radius of a circle inscribed in it. It is written as follows:

Parallelogram It is called a quadrilateral whose opposite sides are parallel to each other. The main tasks at school on this topic are to calculate the area of ​​a parallelogram, its perimeter, height, diagonals. These quantities and formulas for their calculation will be given below.

Parallelogram Properties

Opposite sides of a parallelogram and opposite angles are equal to each other:
AB=CD, BC=AD ,

The diagonals of a parallelogram at the point of intersection are divided into two equal parts:

AO=OC, OB=OD.

Angles adjacent to either side (adjacent angles) add up to 180 degrees.

Each of the diagonals of a parallelogram divides it into two triangles of equal area and geometric dimensions.

Another remarkable property that is often used in solving problems is that the sum of the squares of the diagonals in a parallelogram is equal to the sum of the squares of all sides:

AC^2+BD^2=2*(AB^2+BC^2) .

The main features of parallelograms:

1. A quadrilateral whose opposite sides are pairwise parallel is a parallelogram.
2. A quadrilateral with equal opposite sides is a parallelogram.
3. A quadrilateral with equal and parallel opposite sides is a parallelogram.
4. If the diagonals of the quadrilateral at the point of intersection are divided in half, then this is a parallelogram.
5. A quadrilateral whose opposite angles are equal in pairs is a parallelogram

Bisectors of a parallelogram

Bisectors of opposite angles in a parallelogram can be parallel or coincide.

Bisectors of adjacent angles (adjacent to one side) intersect at right angles (perpendicular).

Parallelogram height

Parallelogram height- this is a segment that is drawn from an angle perpendicular to the base. It follows from this that two heights can be drawn from each angle.

Parallelogram area formula

Parallelogram area is equal to the product of a side and the height drawn to it. The area formula is as follows

The second formula is no less popular in calculations and is defined as follows: the area of ​​​​a parallelogram is equal to the product of adjacent sides by the sine of the angle between them

Based on the above formulas, you will know how to calculate the area of ​​a parallelogram.

Parallelogram perimeter

The formula for calculating the perimeter of a parallelogram is

that is, the perimeter is double value the sums of the parties. Tasks on a parallelogram will be considered in neighboring materials, but for now, study the formulas. Most of the tasks for calculating the sides, diagonals of a parallelogram are quite simple and come down to knowing the sine theorem and the Pythagorean theorem.

The area of ​​a parallelogram. In very many geometry problems related to the calculation of areas, including assignments for the USE, the formulas for the area of ​​​​a parallelogram and a triangle are used. There are several of them, here we will consider them with you.

It would be too easy to list these formulas, this goodness is already enough in reference books and on various sites. I would like to convey the essence - so that you do not memorize them, but understand and can easily remember at any time. After studying the material of the article, you will understand that these formulas do not need to be taught at all. Objectively speaking, they occur so often in decisions that they are stored in memory for a long time.

1. So let's look at a parallelogram. The definition reads:

Why is that? Everything is simple! To clearly show what the meaning of the formula is, let's perform some additional constructions, namely, we will build the heights:

The area of ​​the triangle (2) is equal to the area of ​​the triangle (1) - the second sign of the equality of right-angled triangles "along the leg and hypotenuse." Now we mentally “cut off” the second one and transfer it by superimposing it on the first one - we get a rectangle, the area of ​​\u200b\u200bwhich will be equal to the area of ​​the original parallelogram:

The area of ​​a rectangle, as you know, is equal to the product of its adjacent sides. As can be seen from the sketch, one side of the resulting rectangle is equal to the side of the parallelogram, and the other side is equal to the height of the parallelogram. Therefore, we obtain the formula for the area of ​​a parallelogram S = a∙h a

2. Let's continue, one more formula for its area. We have:

Parallelogram area formula

Let's denote the sides as a and b, the angle between them γ "gamma", the height h a. Consider right triangle:

As in Euclidean geometry, the point and the line are the main elements of the theory of planes, so the parallelogram is one of key figures convex quadrilaterals. From it, like threads from a ball, flow the concepts of "rectangle", "square", "rhombus" and other geometric quantities.

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Definition of a parallelogram

convex quadrilateral, consisting of segments, each pair of which is parallel, is known in geometry as a parallelogram.

What a classic parallelogram looks like is a quadrilateral ABCD. The sides are called the bases (AB, BC, CD and AD), the perpendicular drawn from any vertex to the opposite side of this vertex is called the height (BE and BF), the lines AC and BD are the diagonals.

Attention! Square, rhombus and rectangle are special cases of parallelogram.

Sides and angles: ratio features

Key properties, by and large, predetermined by the designation itself, they are proved by the theorem. These characteristics are as follows:

1. Sides that are opposite are identical in pairs.
2. Angles that are opposite to each other are equal in pairs.

Proof: consider ∆ABC and ∆ADC, which are obtained by dividing quadrilateral ABCD by line AC. ∠BCA=∠CAD and ∠BAC=∠ACD, since AC is common to them (vertical angles for BC||AD and AB||CD, respectively). It follows from this: ∆ABC = ∆ADC (the second criterion for the equality of triangles).

Segments AB and BC in ∆ABC correspond in pairs to lines CD and AD in ∆ADC, which means that they are identical: AB = CD, BC = AD. Thus, ∠B corresponds to ∠D and they are equal. Since ∠A=∠BAC+∠CAD, ∠C=∠BCA+∠ACD, which are also identical in pairs, then ∠A = ∠C. The property has been proven.

Characteristics of the figure's diagonals

Main feature these parallelogram lines: the point of intersection bisects them.

Proof: let m. E be the intersection point of the diagonals AC and BD of the figure ABCD. They form two commensurate triangles - ∆ABE and ∆CDE.

AB=CD since they are opposite. According to lines and secants, ∠ABE = ∠CDE and ∠BAE = ∠DCE.

According to the second sign of equality, ∆ABE = ∆CDE. This means that the elements ∆ABE and ∆CDE are: AE = CE, BE = DE and, moreover, they are commensurate parts of AC and BD. The property has been proven.

Features of adjacent corners

At adjacent sides, the sum of the angles is 180°, since they lie on the same side of the parallel lines and the secant. For quadrilateral ABCD:

∠A+∠B=∠C+∠D=∠A+∠D=∠B+∠C=180º

Bisector properties:

1. , dropped to one side, are perpendicular;
2. opposite vertices have parallel bisectors;
3. the triangle obtained by drawing the bisector will be isosceles.

Determining the characteristic features of a parallelogram by the theorem

The features of this figure follow from its main theorem, which reads as follows: quadrilateral is considered a parallelogram in the event that its diagonals intersect, and this point divides them into equal segments.

Proof: Let lines AC and BD of quadrilateral ABCD intersect in t. E. Since ∠AED = ∠BEC, and AE+CE=AC BE+DE=BD, then ∆AED = ∆BEC (by the first sign of equality of triangles). That is, ∠EAD = ∠ECB. They are also the interior crossing angles of the secant AC for lines AD and BC. Thus, by definition of parallelism - AD || BC. A similar property of the lines BC and CD is also derived. The theorem has been proven.

Calculating the area of ​​a figure

The area of ​​this figure found in several ways one of the simplest: multiplying the height and the base to which it is drawn.

Proof: Draw perpendiculars BE and CF from vertices B and C. ∆ABE and ∆DCF are equal since AB = CD and BE = CF. ABCD is equal to the rectangle EBCF, since they also consist of proportionate figures: S ABE and S EBCD, as well as S DCF and S EBCD. It follows from this that the area of ​​this geometric figure is located in the same way as a rectangle:

S ABCD = S EBCF = BE×BC=BE×AD.

To determine the general formula for the area of ​​a parallelogram, we denote the height as hb, and the side b. Respectively:

Other ways to find area

Area calculations through the sides of the parallelogram and the angle, which they form, is the second known method.

,

Spr-ma - area;

a and b are its sides

α - angle between segments a and b.

This method is practically based on the first, but in case it is unknown. always cuts off a right triangle whose parameters are trigonometric identities, that is . Transforming the ratio, we get . In the equation of the first method, we replace the height with this product and obtain a proof of the validity of this formula.

Through the diagonals of a parallelogram and an angle, which they create when they intersect, you can also find the area.

Proof: AC and BD intersecting form four triangles: ABE, BEC, CDE and AED. Their sum is equal to the area of ​​this quadrilateral.

The area of ​​each of these ∆ can be found from the expression , where a=BE, b=AE, ∠γ =∠AEB. Since , then a single value of the sine is used in the calculations. That is . Since AE+CE=AC= d 1 and BE+DE=BD= d 2 , the area formula reduces to:

.

Application in vector algebra

The features of the constituent parts of this quadrangle have found application in vector algebra, namely: the addition of two vectors. The parallelogram rule states that if given vectors andnotare collinear, then their sum will be equal to the diagonal of this figure, the bases of which correspond to these vectors.

Proof: from an arbitrarily chosen beginning - that is. - we build vectors and . Next, we build a parallelogram OASV, where the segments OA and OB are sides. Thus, the OS lies on the vector or sum.

Formulas for calculating the parameters of a parallelogram

The identities are given under the following conditions:

1. a and b, α - sides and the angle between them;
2. d 1 and d 2 , γ - diagonals and at the point of their intersection;
3. h a and h b - heights lowered to sides a and b;

Parameter	Formula
Finding sides
along the diagonals and the cosine of the angle between them
diagonally and sideways
through height and opposite vertex
Finding the length of the diagonals
on the sides and the size of the top between them

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