A Quadrilateral is a two-dimensional closed shape formed by four straight line segments. It has four sides, four vertices (corners), and four interior angles. The sum of all interior angles of a quadrilateral is always 360°.
Quadrilaterals are either simplex (not self-intersecting), or complex (self-intersecting). Simple quadrilaterals are further divided into concave and convex.
Properties of a Quadrilateral
- It has four sides: AB, BC, CD, and DA.
- It has four vertices: A, B, C, and D.
- It has four angles: ∠DAB, ∠ABC, ∠BCD, and ∠CDA.
- ∠A and ∠B are adjacent angles.
- ∠A and ∠C are opposite angles.
- AB and CD are opposite sides.
- AB and BC are adjacent sides.
Simple Quadrilateral
A simple quadrilateral is a quadrilateral in which the sides do not intersect each other. It is a closed figure made of four straight line segments.
Convex Quadrilaterals
A convex quadrilateral is a four-sided shape in which all interior angles are less than 180°, so the shape does not bend inward, and both diagonals lie completely inside the figure.
- Irregular Quadrilateral: A quadrilateral with four sides that are unequal in length and angles.
- Trapezium (Trapezoid): A quadrilateral with one pair of opposite sides parallel.
- Isosceles Trapezium (Isosceles Trapezoid): A trapezium whose non-parallel sides are equal and whose base angles are equal.
- Parallelogram: A quadrilateral with both pairs of opposite sides parallel.
- Kite: A quadrilateral with two pairs of adjacent sides equal.
- Rhombus: A quadrilateral with all four sides equal.
- Rectangle: A quadrilateral with all interior angles equal to 90°.
- Square: A quadrilateral with all sides equal and all angles equal to 90°.
Concave Quadrilateral
A concave quadrilateral is a quadrilateral in which at least one interior angle is greater than 180°. Because of this, one of its diagonals lies partially or completely outside the figure.
Complex Quadrilateral
A complex quadrilateral is a quadrilateral in which the sides intersect each other, so the figure is self-crossing instead of simple.
Quadrilateral Theorems
- Sum of Interior Angles Theorem: In any quadrilateral, the sum of all four interior angles is always 360 degrees. This is true for all four-sided shapes, whether regular or irregular.
- Opposite Angles Theorem: In a quadrilateral, the sum of two opposite angles is 180 degrees. For example, in a parallelogram, each pair of opposite angles adds up to 180°.
- Consecutive Angles Theorem: Adjacent (consecutive) angles in a quadrilateral are supplementary, meaning their sum is 180 degrees. This is particularly useful for parallelograms and trapeziums.
- Diagonals of Parallelograms Theorem: The diagonals of a parallelogram bisect each other, dividing each diagonal into two equal parts. This property helps in proving congruence in triangles inside the parallelogram.
- Opposite Sides and Angles of Parallelograms Theorem: In a parallelogram, opposite sides are equal in length and opposite angles are equal. This is why squares, rectangles, and rhombuses share this property.
- Diagonals of Rectangles and Rhombuses Theorem: In a rectangle, the diagonals are equal in length. In a rhombus, the diagonals bisect each other at right angles. In both shapes, the diagonals divide the shape into congruent triangles.
- Diagonals of Trapezoids Theorem: The diagonals of a trapezoid may be of different lengths. However, the line joining the midpoints of the non-parallel sides is always parallel to the bases and its length is half the sum of the parallel sides.
Quadrilateral Lines of Symmetry
A line of symmetry is an imaginary line that divides a shape into two identical halves, so that one half is a mirror image of the other.
In quadrilaterals:
- A line of symmetry can pass through vertices or midpoints of sides.
- When folded along the line, the two halves match exactly.
Examples:
- A square has four lines of symmetry: two along the diagonals and two along the lines joining the midpoints of opposite sides.
- A rectangle has two lines of symmetry, both joining the midpoints of opposite sides.
- Other quadrilaterals may have no lines of symmetry or fewer lines depending on their shape.
Learn in Detail
- Construction of a Quadrilateral
- Types and their Properties
- Formulas
- Area and Perimeter
- Real-Life Applications
- Practice Questions
Solved Examples on Quadrilaterals
Question 1: The perimeter of quadrilateral ABCD is 46 units. AB = x + 7, BC = 2x + 3, CD = 3x - 8, and DA = 4x - 6. Find the length of the shortest side of the quadrilateral.
Solution:
Perimeter = Sum of all sides
= 46 = 10x - 4 or [x = 5]
That gives, AB = 12 units, BC = 13 units, CD = 7 units, DC = 14 units
Hence, length of shortest side is 7 units (i.e. CD).
Question 2: Given a trapezoid ABCD (AB || DC) with median EF. AB = 3x - 5, CD = 2x -1 and EF = 2x + 1. Find the value of EF.
Solution:
We know that the Median of the trapezoid is half the sum of its bases.
= EF = (AB + CD) / 2
= 4x + 2 = 5x - 6 or [x = 8]
Therefore EF = 2x + 1 = 2(8) + 1 => EF = 17 units.
Question 3: In a Parallelogram, adjacent angles are in the ratio of 1:2. Find the measures of all angles of this Parallelogram.
Solution:
Let the adjacent angle be x and 2x.
We know that in of a Parallelogram adjacent angles are supplementary.
= x + 2x = 180° or [x = 60°]
Also, opposite angles are equal in a Parallelogram.
Therefore measures of each angles are 60°, 120°, 60°, 120°.
