Polygons

Given: Number of sides of polygon = 52

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (52 – 2) × 180°

⇒ S = 50 × 180°

⇒ S = 9000

∴ The sum of the angles of 52-sided polygon is 9000°.

Given: Sum of the angles = 8100°

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ 8100° = (n – 2) × 180°

⇒

⇒ 45 = n – 2

⇒ n = 45 + 2

⇒ n = 47

∴ The number of sides of polygon having sum of the angles of 8100° is 47 sides.

Given: Sum of the angles = 1600° and 900°

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ 1600° = (n – 2) × 180°

⇒

⇒ 8.89 = n – 2

⇒ n = 8.89 + 2

⇒ n = 10.89

∴ There is no polygon which have sum of the angles as 1600°.

When sum is 900°

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ 900° = (n – 2) × 180°

⇒

⇒ 5 = n – 2

⇒ n = 5 + 2

⇒ n = 7

∴ The number of sides of polygon having sum of the angles of 900° is 7 sides.

Given: Number of sides of polygon = 20

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (20 – 2) × 180°

⇒ S = 18 × 180°

⇒ S = 3240

∴ The sum of the angles of 20-sided polygon is 3240°.

Given: Sum of the angles = 1980°

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ 1980° = (n – 2) × 180°

⇒

⇒ 11 = n – 2

⇒ n = 11 + 2

⇒ n = 13

∴ The number of sides of polygon having sum of the angles of 1980° is 13 sides.

When the number of sides of polygon one side less than 13-sided polygon.

Number of sides of polygon = 12

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (12 – 2) × 180°

⇒ S = 10 × 180°

⇒ S = 1800

∴ The sum of the angles of 12-sided polygon is 1800°.

When the number of sides of polygon one side more than 13-sided polygon.

Number of sides of polygon = 14

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (14 – 2) × 180°

⇒ S = 12 × 180°

⇒ S = 2160

∴ The sum of the angles of 14-sided polygon is 2160°.

Given:

In Δ ABC

∠A + ∠B + ∠C = 180° (sum of the angles of triangle = 180°)

⇒ 60° + 40° + ∠C = 180°

⇒ 100° + ∠C = 180°

⇒ ∠C = 180° - 100°

⇒ ∠C = 80°

∠ACJ + ∠ ACB = 180° (linear pair of angles at a vertex.)

⇒ ∠ ACJ + 80° = 180°

⇒ ∠ ACJ = 180° - 80°

⇒ ∠ ACJ = 140°

∠CBI + ∠CBA = 180° (linear pair of angles at a vertex.)

⇒ ∠CBI + 40° = 180°

⇒ ∠CBI = 180° - 40°

⇒ ∠CBI = 140°

∠ BAH + ∠ BAC = 180° (linear pair of angles at a vertex.)

⇒ ∠BAH + 60° = 180°

⇒ ∠BAH = 180° - 60°

⇒ ∠BAH = 120°

Let us name the different coordinate in the above question figure:

∠ CBI + ∠ CBA = 180° (linear pair of angles at a vertex)

⇒ 105° + ∠ CBA = 180°

⇒ ∠ CBA = 180° - 105°

⇒ ∠ CBA = 65°

∠ BAH + ∠ BAC = 180° (linear pair of angles at a vertex)

⇒ ∠ BAH + 35° = 180°

⇒ ∠ BAH = 180° - 35°

⇒ ∠ BAH = 145°

In Δ ABC,

∠ A + ∠ B + ∠ C = 180° (Sum of the angles of triangle is 180°)

⇒ 35° + 65° + ∠ C = 180°

⇒ 100° + ∠ C = 180°

⇒ ∠ C = 180° - 100°

⇒ ∠ C = 80°

∠ ACB + ∠ ACJ = 180° (linear pair of angles at a vertex)

⇒ 80° + ∠ ACJ = 180°

⇒ ∠ ACJ = 180° - 80°

⇒ ∠ ACJ = 140°

Let us name the different coordinate in the above question figure:

Sum of the angles of 4-sided polygon

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (4 – 2) × 180°

⇒ S = 2 × 180°

⇒ S = 360°

In ABCD

∠ A + ∠ B + ∠ C + ∠ D = 360°

⇒ 130° + 70° + 60° + ∠ D = 360°

⇒ 260° + ∠ D = 360°

⇒ ∠ D = 360° - 260°

⇒ ∠ D = 100°

Exterior Angles

∠ FAB + ∠ DAB = 180° (linear pair of angles at a vertex)

⇒ ∠ FAB + 130° = 180°

⇒ ∠ FAB = 180° - 130°

⇒ ∠ FAB = 50°

∠ CBE + ∠ CBA = 180° (linear pair of angles at a vertex)

⇒ ∠ CBE + 70° = 180°

⇒ ∠ CBE = 180° - 70°

⇒ ∠ CBE = 110°

∠ DCB + ∠ DCH = 180° (linear pair of angles at a vertex)

⇒ 60° + ∠ DCH = 180°

⇒ ∠ DCH = 180° - 60°

⇒ ∠ DCH = 120°

∠ ADG + ∠ ADC = 180° (linear pair of angles at a vertex)

⇒ ∠ ADG + 100° = 180°

⇒ ∠ ADG = 180° - 100°

⇒ ∠ ADG = 80°

Let us name the vertices of the triangle.

∠ ABC + ∠ ABD = 180°

⇒ ∠ ABC + 145° = 180°

⇒ ∠ ABC = 180° - 145°

⇒ ∠ ABC = 35°

In Δ ABC,

∠ A + ∠ B + ∠ C = 180°

⇒ ∠ A + 35° + 70° = 180°

⇒ ∠ A + 105° = 180°

⇒ ∠ A = 180° - 105°

⇒ ∠ A = 75°

∠ CAF + ∠ CAB = 180°

⇒ ∠ CAF + 75° = 180°

⇒ ∠ CAF = 180° - 75°

⇒ ∠ CAF = 105°

∠ BCE + ∠ BCA = 180°

⇒ ∠ BCE + 70° = 180°

⇒ ∠ BCE = 180° - 70°

⇒ ∠ BCE = 110°

Let us name the vertices of quadrilateral.

∠ CDA + ∠ CDE = 180° (linear pair of angles at a vertex)

⇒ ∠ CDA + 115° = 180°

⇒ ∠ CDA = 180° - 115°

⇒ ∠ CDA = 65°

Sum of the angles of 4-sided polygon

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (4 – 2) × 180°

⇒ S = 2 × 180°

⇒ S = 360°

In ABCD

∠ A + ∠ B + ∠ C + ∠ D = 360°

⇒ ∠ A + 100° + 75° + 65° = 360°

⇒ 240° + ∠ A = 360°

⇒ ∠ A = 360° - 240°

⇒ ∠ A = 120°

∠ DAH + ∠ DAB = 180° (linear pair of angles at a vertex)

⇒ ∠ DAH + 120° = 180°

⇒ ∠ DAH = 180° - 120°

⇒ ∠ DAH = 60°

∠ ABG + ∠ ABC = 180° (linear pair of angles at a vertex)

⇒ ∠ ABG + 100° = 180°

⇒ ∠ ABG = 180° - 100°

⇒ ∠ ABG = 80°

∠ BCF + ∠ BCD = 180° (linear pair of angles at a vertex)

⇒ ∠ BCF + 75° = 180°

⇒ ∠ BCF = 180° - 75°

⇒ ∠ BCF = 105°

Let us name the vertices of quadrilateral

∠ ADC + ∠ ADE = 180° (linear pair of angles at a vertex)

⇒ ∠ ADC + 80° = 180°

⇒ ∠ ADC = 180° - 80°

⇒ ∠ ADC = 100°

∠ DCB + ∠ DCJ = 180° (linear pair of angles at a vertex)

⇒ ∠ DCB + 95° = 180°

⇒ ∠ DCB = 180° - 95°

⇒ ∠ DCB = 85°

Sum of the angles of 4-sided polygon

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (4 – 2) × 180°

⇒ S = 2 × 180°

⇒ S = 360°

In ABCD

∠ A + ∠ B + ∠ C + ∠ D = 360°

⇒ ∠ A + 85° + 85° + 100° = 360°

⇒ 270° + ∠ A = 360°

⇒ ∠ A = 360° - 270°

⇒ ∠ A = 90°

∠ BAG + ∠ BAD = 180°

⇒ ∠ BAG + 90° = 180°

⇒ ∠ BAG = 180° - 90°

⇒ ∠ BAG = 90°

∠ BAG = ∠ DAF (opposite angle at a vertex)

∠ DAF = 90°

∠ DAB = ∠ GAF (opposite angle at a vertex)

∠ GAF = 90°

Let us consider Δ ABC and ∠ ACD is and exterior angle

To show: ∠ ACD = ∠ A + ∠ B

Through C draw CE parallel to AB

Proof:

∠ A = ∠ y (AB || CE and AD is a transversal)

∠ B = ∠ x (AB || CE and AC is a transversal; alternate angles are equal)

∠ 1 + ∠ 2 = ∠ x + ∠ y

Now, ∠ x + ∠ y = ∠ ACD

Hence, ∠ 1 + ∠ 2 = ∠ ACD

∠ ACD = ∠ A + ∠ B

Hence Proved.

We know that,

Sum of outer angles of any polygon = 360°

Sum of each exterior angle

Sum of each exterior angle of 18-sided polygon

Let SP be the transversal and PQ || RS

∠ P + ∠ S = 180° (consecutive interior angle adds up to 180°)

⇒ 50° + ∠ S = 180°

⇒ ∠ S = 180° - 50°

⇒ ∠ S = 130°

Let RQ be the transversal and PQ || RS

∠ R + ∠ Q = 180° (consecutive interior angle adds up to 180°)

⇒ 110° + ∠ Q = 180°

⇒ ∠ Q = 180° - 110°

⇒ ∠ Q = 70°

The sum of inner and outer angle at vertex is 180°.

∠ P + ext.∠ P = 180°

⇒ 50° + ext. ∠ P = 180°

⇒ ext. ∠ P = 180° - 50°

⇒ ext. ∠ P = 130°

∠ Q + ext.∠ Q = 180°

⇒ 70° + ext. ∠ Q = 180°

⇒ ext. ∠ Q = 180° - 70°

⇒ ext. ∠ Q = 110°

∠ R + ext.∠ R = 180°

⇒ 110° + ext. ∠ R = 180°

⇒ ext. ∠ R = 180° - 110°

⇒ ext. ∠ R = 70°

∠ S + ext.∠ S = 180°

⇒ 130° + ext. ∠ S = 180°

⇒ ext. ∠ S = 180° - 130°

⇒ ext. ∠ S = 50°

∠ ADC + ∠ CDF = 180° (linear pair of angles at a vertex)

∠ CDF = 180° - ∠ ADC …(1)

∠ ABC + ∠ CBE = 180° (linear pair of angles at a vertex)

∠ CBE = 180° - ∠ ABC … (2)

Sum of two exterior angles marked.

⇒ ∠ CBE + ∠ CDF = 180° - ∠ ABC + 180° - ∠ ADC

⇒ ∠ CBE + ∠ CDF = 360° - (∠ ABC + ∠ ADC) …(3)

In ABCD

∠ ABC + ∠ BCD + ∠ ADC + ∠ DAB = 360°

[sum of all interior angles 4-sided polygon is 360°]

⇒ ∠ ABC + ∠ ADC = 360° - ∠ BCD - ∠ DAB

Put this value in equation (3)

⇒ ∠ CBE + ∠ CDF = 360° - (360° - ∠ BCD - ∠ DAB)

⇒ ∠ CBE + ∠ CDF = 360° - 360° + ∠ BCD + ∠ DAB

⇒ ∠ CBE + ∠ CDF = ∠ BCD + ∠ DAB

Hence, yes there is a relation between the sum of exterior angles marked and sum of inner angles at the other two vertices.

Let x be the measure of inner angle and 2x be the measure of outer angle.

Assume that the regular polygon has n sides (or angles)

Sum of the interior angles = (n – 2) × 180°

n × x = (n – 2) × 180°

⇒ nx = (n – 2) × 180° … (1)

Sum of the exterior angle = 360°

⇒ n × 2x = 360°

⇒ 2nx = 360°

⇒

Substitute this value for x in equation (1)

⇒

⇒ 180° = 180°n – 360°

⇒ 180° = 180°n – 360°

⇒ 180°n = 180° + 360°

⇒ 180°n = 540°

⇒

⇒ n = 3

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (3 – 2) × 180°

⇒ S = 1 × 180°

⇒ S = 180°

Measure of each interior angle

⇒ x°

i. Measure of each interior angle is 60°

ii. Number of sides of this polygon is 3.

As we know the sum of exterior angles in each polygon is 360°.

Let n be the number of angles in the polygon.

Then the sum of interior angle is (n – 2) × 180°

Since the sum of interior angle is twice the sum of exterior angles

⇒ (n – 2) × 180° = 2 × 360°

⇒

⇒ (n – 2) = 2 × 2

⇒ (n – 2) = 4

⇒ n = 4 + 2

⇒ n = 6

Since the sum of exterior angle is half the sum of interior angles

⇒

⇒ (n – 2) × 180° = 2 × 360°

⇒

⇒ (n – 2) = 2 × 2

⇒ (n – 2) = 4

⇒ n = 4 + 2

⇒ n = 6

Since the sum of interior angle is equal to the sum of exterior angles

⇒ (n – 2) × 180° = 360°

⇒

⇒ n – 2 = 2

⇒ n = 2 + 2

⇒ n = 4

Given: number of side of polygon = 15

Measure of each exterior angle

⇒ ext. ∠ x

⇒ ext. ∠ x = 24°

The sum of inner and outer angle at vertex is 180°.

∠ x + ext. ∠ x = 180°

⇒ ∠ x + 24° = 180°

⇒ ∠ x = 180° - 24°

⇒ ∠ x = 156°

Measure of interior angles is 156° and exterior angle is 24°.

Each interior angle

⇒

⇒ 168°n = 180°n – 360°

⇒ 168°n + 360° = 180°n

⇒ 360° = 180°n – 168°n

⇒ 360° = 12°n

⇒

⇒ n = 30

We know that,

Sum of exterior angles = 360°

Measure of each exterior angle

⇒

⇒ 6°n = 360°

⇒

⇒ n = 60

Yes, we can draw regular polygon with each outer angle 6°

Sum of exterior angles = 360°

Measure of each exterior angle

⇒

⇒ 7°n = 360°

⇒

⇒ n = 51.42

No, we cannot draw regular polygon with each outer angle 6°

In regular pentagon,

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (5 – 2) × 180°

⇒ S = 3 × 180°

⇒ S = 540°

Measure of each interior angle

⇒

In regular hexagon,

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (6 – 2) × 180°

⇒ S = 4 × 180°

⇒ S = 720°

Measure of each interior angle

⇒

Let us assume the point opposite to Q as S.

∠ PQS + ∠ RQS + ∠ PQR = 360° (pair of angles at a vertex)

⇒ 120° + 108° + ∠ PQR = 360°

⇒ 228° + ∠ PQR = 360°

⇒ ∠ PQR = 360° - 228°

⇒ ∠ PQR = 132°

We know that, all angles of square are 90°.

In regular pentagon,

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (5 – 2) × 180°

⇒ S = 3 × 180°

⇒ S = 540°

Measure of each interior angle

⇒

In regular hexagon,

Sum of the angles of n-sided polygon = (n – 2) × 180°

⇒ S = (6 – 2) × 180°

⇒ S = 4 × 180°

⇒ S = 720°

Measure of each interior angle

⇒

Let us assume the two points adajacent A as P and L.

∠ BAP + ∠ BAC + ∠ CAL + ∠ PAL = 360° (pair of angles at a vertex)

⇒ 120° + 108° + 90° + ∠ BAC = 360°

⇒ 318° + ∠ BAC = 360°

⇒ ∠ BAC = 360° - 318°

⇒ ∠ BAC = 42°

Construction: Draw a perpendicular AO on BF

All the angles are 120° as it is regular hexagon and all the sides are equal.

Now in Δ AOB and Δ AOF,

AO = AO [common]

AB = AF [all sides are equal]

∠ AOB = ∠ AOF = 90° [by construction]

So, Δ AOB ≅ Δ AOF

∠ BAO = ∠ FAO = 60° [CPCT]

∠ ABO = ∠ AFO [CPCT] … (1)

Similarly, Δ BGC ≅ Δ DGC

∠ BCG = ∠ DCG = 60°

∠ CBG = ∠ CDG … (2)

Similarly, Δ DHE ≅ Δ FHE

∠ DEH = ∠ FEH = 60°

∠ EDH = ∠ EFH … (3)

In Δ BAO,

∠ BAO + ∠ AOB + ∠ ABO = 180°

⇒ 60° + 90° + ∠ ABO = 180°

⇒ 150° + ∠ ABO = 180°

⇒ ∠ ABO = 180° - 150°

⇒ ∠ ABO = 30°

∴ from (1) ∠ ABO = ∠ AFO = 30°

Similarly

∠ CBG = ∠ CDG = 30°

∠ EDH = ∠ EFH = 30°

∠ ABO + ∠ FBD + ∠ CBG = ∠ ABC

⇒ 30° + ∠ FBD + 30° = 120°

⇒ ∠ FBD + 60° = 120°

⇒ ∠ FBD = 120° - 60°

⇒ ∠ FBD = 60°

Similarly,

∠ BDF = DFB = 60°

In Δ BDF

∠ FBD = ∠ BDF = DFB = 60°

∴ Δ BDF is an equilateral triangle.

In Δ ABC and Δ FED

AB = FE [sides of hexagon]

BC = ED [sides of hexagon]

∠ ABC = ∠ FED = 120°

∴ Δ ABC ≅ Δ FED

AC = FD [CPCT]

In Δ ABC

∠ BAC = ∠ BCA [angle made on opposite sides]

∠ BAC + ∠ BCA + ∠ ABC = 180°

2∠ BCA + 120° = 180°

⇒ 2 ∠ BCA = 180° - 120°

⇒ 2∠ BCA = 60°

⇒

∴ ∠ BCA = ∠ BAC = 30°

Similarly, ∠ EFD = ∠ EDF = 30°

∠ BCD = ∠ BCA + ∠ ACD

⇒ 120° = 30° + ∠ ACD

⇒ ∠ ACD = 120° - 30°

⇒ ∠ ACD = 90°

∠ EDC = ∠ FDE + ∠ FDC

⇒ 120° = 30° + ∠ FDC

⇒ ∠ FDC = 120° - 30°

⇒ ∠ FDC = 90°

∴ From above calculations AC = FD and AF = CD and ∠ FDC = ∠ ACD = 90°

∴ ACDF is a rectangle.