A plane figure bounded by four sides is called a quadrilateral. In the following figure, four-line segments AB, BC, CD and DA bound a quadrilateral ABCD.
In the given figure, we have.
(i) The points A, B, C and D are the vertices of quadrilateral ABCD.
(ii) The line segments AB, BC, CD and DA are the sides of quadrilateral ABCD.
(iii) The line segments AC and BD are called the diagonals of quadrilateral ABCD.
Note:
(i) Two sides having a common end point are called adjacent sides.
(ii) Two sides having no common end point are called opposite sides.
(iii) Two angles of a quadrilateral having a common arm are called consecutive angles.
(iv) Two angles of a quadrilateral having no common arm are called its opposite angles.
The sum of all the four angles of a quadrilateral is 360º
Let us prove it:
In a quadrilateral ABCD, join BD. Since, the sum of the angles of a triangle is 180º.
∴ In ΔABD, we have
∠1 + ∠A + ∠2 = 180º …(1)
In ΔBCD, we have
∠3 + ∠C + ∠4 = 180º …(2)
Adding (1) and (2), we get
[∠1 + ∠A + ∠2] + [∠3 + ∠C + ∠4] = 180º + 180º
(∠1 + ∠3) + ∠A + ∠C + (∠2 + ∠4) = 180° + 180°
⇒ ∠B + ∠A + ∠C + ∠D = 360º
[∵ ∠1 + ∠3 = ∠B and ∠2 + ∠4 = ∠D]
∴ ∠A + ∠B + ∠C + ∠D = 360º
Thus, the sum of four angles of a quadrilateral is 360º.
The various types of quadrilaterals are:
(i) Parallelogram:
A quadrilateral in which opposite sides are parallel is called a parallelogram. In the figure, ABCD is a parallelogram. Here, AB || CD and AD || BC.
Also, opposite sides of a parallelogram are equal.
(ii) Rectangle: A parallelogram, each of whose angle is 90º, is called a rectangle.
In the figure, PQRS is a rectangle. We write it as rectangle PQRS.
(iii) Square: A rectangle having all sides equal is called a square. In the figure, LMNO is a square.
(iv) Rhombus: A parallelogram having all sides equal is called a rhombus. In the figure, PQRS is a rhombus.
(v) Trapezium: A quadrilateral in which two opposite sides are parallel and two opposite sides are nonparallel, is called a trapezium. In the figure, BCDE is a trapezium.
Note:
If the two non-parallel sides of a trapezium are equal, then it is called an isosceles trapezium.
(vi) Kite: A quadrilateral in which two pairs of adjacent sides are equal is known as kite. PQRS is a kite such that PQ = QR and PS = RS.
Note:
(i) A square, rectangle and rhombus are all parallelograms.
(ii) A square is a rectangle and also a rhombus, but a rectangle or a rhombus is not a square.
(iii) A parallelogram is a trapezium, but a trapezium is not a parallelogram.
(iv) A kite is not a parallelogram.
1. A diagonal of a parallelogram, divides it into two congruent triangles.
2. In a parallelogram, opposite sides are equal.
3. In a parallelogram, opposite angles are equal.
4. The diagonals of a parallelogram bisect each other.
Statement: “The line segment joining the mid-points of any two sides of a triangle is parallel to the third side and equal to half of it.”
Proof: We have ΔABC in which D and E are the mid-points of AB and AC respectively. Let us join DE and produce it. Draw CF || BA to meet DE (produced) in F.
We have to prove that DE = (1/2)BC and DE || BC.
Now, in ΔAED and ΔCEF, we have
AE = CE [Given]
∠AED = ∠CEF [Vertically opposite angles]
∠DAE = ∠FCE [∵ AB || CF and AC is a transversal]
∴ ΔAED ≌ ΔCEF [ASA criteria]
⇒ Their corresponding parts are equal.
⇒ AD = CF and DE = EF
But AD = BD [∵ D is mid point of AB]
⇒ BD = CF Also, BD || CF [By construction]
⇒ BCFD is a parallelogram.
∴ DF = BC and DF || BC
⇒ (1/2)(DF) = (1/2)
(BC) and DE || BC [∵ DE = EF]
⇒ DE = (1/2)
BC and DE || BC Hence, the line segment joining the mid-points of any two sides of a triangle is parallel to the third side and equal to half of it.
The line drawn through the mid-point of one side of a triangle parallel to another side intersects the third side at its mid-point.
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1. What is the Mid-Point Theorem? |
2. How is the Mid-Point Theorem useful in quadrilaterals? |
3. How can we apply the Mid-Point Theorem in solving problems related to quadrilaterals? |
4. Can the Mid-Point Theorem be used to prove that a quadrilateral is a parallelogram? |
5. What are some real-life applications of the Mid-Point Theorem in quadrilaterals? |
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