Free NCERT Solutions Class 9 Maths Chapter 8 Quadrilaterals (Ex 8.1 & 8.2) PDF

NCERT Solutions for Class 9 Maths Chapter 8 Quadrilaterals provide step-by-step answers for Exercise 8.1 and Exercise 8.2 based on the latest CBSE Class 9 Maths syllabus. This chapter explains the properties of quadrilaterals, conditions to prove a parallelogram, the angle sum property (360°), and the mid-point theorem with proofs and examples. These solutions help students understand geometric reasoning, improve proof-writing skills, and prepare effectively for CBSE Class 9 exams.

NCERT Solutions Class 9 Maths Chapter 8 Quadrilaterals – Free PDF Download

Students studying CBSE Class 9 Maths Chapter 8 Quadrilaterals often need complete solutions in one place for practice and revision. The NCERT Solutions Class 9 Maths Chapter 8 Quadrilaterals PDF provided here includes detailed, step-by-step answers to all questions from Exercise 8.1 and Exercise 8.2, prepared according to the latest NCERT textbook and CBSE 2025–26 syllabus.

Download NCERT Solutions Class 9 Maths Chapter 8 Quadrilaterals PDF

The NCERT Solutions for Class 9 Maths Quadrilaterals provided on this page follow the latest CBSE 2025–26 guidelines and include detailed, question-wise explanations for Exercise 8.1 and Exercise 8.2. Each solution is written in a clear, step-by-step format with proper reasoning, helping students understand how to present proofs correctly in exams.

NCERT Solutions Class 9 Maths Chapter 8 Exercise 8.1

Question 1: The angles of quadrilateral are in the ratio 3: 5: 9: 13. Find all the angles of the quadrilateral.

Answer:

Let the common ratio between the angles be x. Therefore, the angles will be 3x, 5x, 9x, and 13x respectively.

As the sum of all interior angles of a quadrilateral is 360⁰,

=> 3x + 5x + 9x + 13x = 360⁰

=> 30x = 360⁰

=> x = 360⁰ / 30

=> x = 12⁰

Hence, the angles are

3x = 3 × 12⁰ = 36⁰

5x = 5 × 12⁰ = 60⁰

9x = 9 × 12⁰ = 108⁰

13x = 13 × 12⁰ = 156⁰

Question 2: If the diagonals of a parallelogram are equal, then show that it is a rectangle.

Answer:

Let ABCD be a parallelogram. To show that ABCD is a rectangle, we have to prove that one of its interior angles are 90⁰.

In ΔABC and ΔDCB,

AB = DC (Opposite sides of a parallelogram are equal)

BC = BC (Common)

AC = DB (Given)

By SSS congruence rule,

ΔABC ≅ ΔDCB

So, ∠ABC = ∠DCB

It is known that the sum of measures of angles on the same side of traversal is 180⁰.

∠ABC + ∠DCB = 180⁰ [AB || CD]

=> ∠ABC + ∠ABC = 180⁰

=> 2∠ABC = 180⁰

=> ∠ABC = 90⁰

Since ABCD is a parallelogram and one of its interior angles is 90⁰, ABCD is a rectangle.

Question 3: Show that if the diagonals of a quadrilateral bisect each other at right angles, then it is a rhombus.

Answer:

Let ABCD be a quadrilateral, whose diagonals AC and BD bisect each other at right angle i.e.,

OA = OC, OB = OD, and ∠AOB = ∠BOC = ∠COD = ∠AOD = 90⁰.

To prove, ABCD a rhombus, we have to prove ABCD is a parallelogram and all the sides of ABCD are equal.

In ΔAOD and ΔCOD,

OA = OC (Diagonals bisect each other)

∠AOD = ∠COD (Given)

OD = OD (Common)

So, ΔAOD ≅ ΔCOD (By SAS congruence rule)

Hence, AD = CD ………….. (1)

Similarly, it can be proved that

AD = AB and CD = BC ……….. (2)

From equation (1) and (2), we get

AB = BC = CD = AD

Since opposite sides of quadrilateral ABCD are equal, it can be said that ABCD is a parallelogram. Since all sides of a parallelogram ABCD are equal, it can be said that ABCD is a rhombus.

Question 4: Show that the diagonals of a square are equal and bisect each other at right angles.

Answer:

Let ABCD be a square. Let the diagonals AC and BD intersect each other at a point O. To prove that the diagonals of a square are equal and bisect each other at right angles, we have to prove AC = BD, OA = OC, OB = OD, and ∠AOB = 90⁰.

In ΔABC and ΔDCB,

AB = DC (Sides of a square are equal to each other)

∠ABC = ∠DCB (All interior angles are of 90⁰)

BC = CB (Common side)

So, ΔABC ≅ ΔDCB (By SAS congruency)

Hence, AC = DB (By CPCT)

Hence, the diagonals of a square are equal in length.

In ΔAOB and ΔCOD,

∠AOB = ∠COD (Vertically opposite angles)

∠ABO = ∠CDO (Alternate interior angles)

AB = CD (Sides of a square are always equal)

So, ΔAOB ≅ ΔCOD (By AAS congruence rule)

Hence, AO = CO and OB = OD (By CPCT)

Hence, the diagonals of a square bisect each other.

In ΔAOB and ΔCOB,

As we had proved that diagonals bisect each other, therefore,

AO = CO

AB = CB (Sides of a square are equal)

BO = BO (Common)

So, ΔAOB ≅ ΔCOB (By SSS congruency)

Hence, ∠AOB = ∠COB (By CPCT)

However, ∠AOB + ∠COB = 180⁰ (Linear pair)

2∠AOB = 180⁰

∠AOB = 90⁰

Hence, the diagonals of a square bisect each other at right angles.

Question 5: Show that if the diagonals of a quadrilateral are equal and bisect each other at right angles, then it is a square.

Answer:

Let us consider a quadrilateral ABCD in which the diagonals AC and BD intersect each other at O. It is given that the diagonals of ABCD are equal and bisect each other at right angles.

Therefore, AC = BD, OA = OC, OB = OD, and ∠AOB = ∠BOC = ∠COD = ∠AOD = 90⁰.

To prove ABCD is a square, we have to prove that ABCD is a parallelogram, AB = BC = CD = AD, and one of its interior angles is 90⁰.

In ΔAOB and ΔCOD,

AO = CO (Diagonals bisect each other)

OB = OD (Diagonals bisect each other)

∠AOB = ∠COD (Vertically opposite angles)

So, ΔAOB ≅ ΔCOD (SAS congruence rule)

Hence AB = CD……………………… (1) (By CPCT)

And, ∠OAB = ∠OCD (By CPCT)

However, these are alternate interior angles for line AB and CD and alternate interior angles are equal to each other only when the two lines are parallel.

So, AB || CD ……………(2)

From equations (1) and (2), we obtain

ABCD is a parallelogram.

In ΔAOD and ΔCOD,

AO = CO (Diagonals bisect each other)

∠AOD = ∠COD (Given that each is 90⁰)

OD = OD (Common)

So, ΔAOD ≅ ΔCOD (SAS congruence rule)

Hence AD = DC …………. (3)

However, AD = BC and AB = CD (Opposite sides of parallelogram ABCD)

=> AB = BC = CD = DA

Therefore, all the sides of quadrilateral ABCD are equal to each other.

In ΔADC and ΔBCD,

AD = BC (Already proved)

AC = BD (Given)

DC = CD (Common)

So, ΔADC ≅ ΔBCD (SSS Congruence rule)

Hence, ∠ADC = ∠BCD (By CPCT)

However, ∠ADC + ∠BCD = 180⁰ (Co-interior angles)

=> ∠ADC + ∠ADC = 180⁰

=> 2∠ADC = 180⁰

=> ∠ADC = 90⁰

One of the interior angles of quadrilateral ABCD is a right angle.

Thus, we have obtained that ABCD is a parallelogram, AB = BC = CD = AD and one of its interior angles is 90⁰. Therefore, ABCD is a square.

Question 6: Diagonal AC of a parallelogram ABCD bisects ∠A (see Fig). Show that

(1) it bisects ∠ C also,

(2) ABCD is a rhombus.

Answer:

(1) ABCD is a parallelogram.

So, ∠DAC = ∠BCA………………………………………….. (1) (Alternate interior angles)

And, ∠BAC = ∠DCA………………………………………… (2) (Alternate interior angles)

However, it is given that AC bisects ∠A.

So, ∠DAC = ∠BAC………………………………………………… (3)

From equations (1), (2), and (3), we obtain

∠DAC = ∠BCA = ∠BAC = ∠DCA ……………… (4)

=> ∠DCA = ∠BCA

Hence, AC bisects ∠C.

(2) From equation (4), we obtain

∠DAC = ∠DCA

=> DA = DC (Side opposite to equal angles are equal)

However, DA = BC and AB = CD (Opposite sides of a parallelogram)

=> AB = BC = CD = DA

Hence, ABCD is a rhombus.

Question 7: ABCD is a rhombus. Show that diagonal AC bisects ∠A as well as ∠C and diagonal BD bisects ∠B as well as ∠D.

Answer:

Join AC.

In ΔABC,

BC = AB (Sides of a rhombus are equal to each other)

So, ∠1 = ∠2 (Angles opposite to equal sides of a triangle are equal)

However, ∠1 = ∠3 (Alternate interior angles for parallel lines AB and CD)

=> ∠2 = ∠3

Therefore, AC bisects ∠C.

Also, ∠2 = ∠4 (Alternate interior angles for || lines BC and DA)

=> ∠1 = ∠4

Therefore, AC bisects ∠A.

Similarly, it can be proved that BD bisects ∠B and ∠D as well.

Question 8:

ABCD is a rectangle in which diagonal AC bisects ∠A as well as ∠C. Show that:

(1) ABCD is a square

(2) diagonal BD bisects ∠B as well as ∠D.

Answer:

(1) It is given that ABCD is a rectangle.

So, ∠A = ∠C

=> ∠A/2 = ∠C/2

=> ∠DAC = ∠DCA [AC bisects ∠A and ∠C]

CD = DA [Sides opposite to equal angles are also equal]

However, DA = BC and BC = CD [Opposite sides of a rectangle are equal]

=> AB = BC = CD = DA

ABCD is a rectangle and all of its sides are equal.

Hence, ABCD is a square.

(2) Let us join BD.

In ΔBCD,

BC = CD (Sides of a square are equal to each other)

∠CDB = ∠CBD (Angles opposite to equal sides are equal)

However, ∠CDB = ∠ABD (Alternate interior angles for AB || CD)

=> ∠CBD = ∠ABD

=> BD bisects B.

Also, ∠CBD = ∠ADB (Alternate interior angles for BC || AD)

=> ∠CDB = ∠ABD

So, BD bisects ∠D.

Question 9: In parallelogram ABCD, two points P and Q are taken on diagonal BD such that DP = BQ (see the given figure). Show that:

(1) ΔAPD ≅ ΔCQB

(2) AP = CQ

(3) ΔAQB ≅ ΔCPD

(4) AQ = CP

(5) APCQ is a parallelogram

Answer:

(1) In ΔAPD and ΔCQB,

∠ADP = ∠CBQ (Alternate interior angles for BC || AD) AD = CB (Opposite sides of parallelogram ABCD)

DP = BQ (Given)

ΔAPD ≅ ΔCQB (Using SAS congruence rule)

(2) As we had observed that ΔAPD ≅ ΔCQB,

AP = CQ (CPCT)

(3) In ΔAQB and ΔCPD,

∠ABQ = ∠CDP (Alternate interior angles for AB || CD) AB = CD (Opposite sides of parallelogram ABCD)

BQ = DP (Given)

ΔAQB ≅ ΔCPD (Using SAS congruence rule)

(4) As we had observed that ΔAQB ≅ ΔCPD,

AQ = CP (CPCT)

(5) From the result obtained in (2) and (4),

AQ = CP and AP = CQ

Since opposite sides in quadrilateral APCQ are equal to each other, APCQ is a parallelogram.

Question 10: ABCD is a parallelogram and AP and CQ are perpendiculars from vertices A and C on diagonal BD (See the given figure). Show that:

(1) ΔAPB ≅ ΔCQD

(2) AP = CQ

Answer:

(1) In ΔAPB and ΔCQD,

∠APB = ∠CQD (Each 90⁰)

AB = CD (Opposite sides of parallelogram ABCD)

∠ABP = ∠CDQ (Alternate interior angles for AB || CD)

ΔAPB ≅ ΔCQD (By AAS congruency)

(2) By using the above result

ΔAPB ≅ ΔCQD, we obtain

AP = CQ (By CPCT)

Question 11: In ΔABC and ΔDEF, AB = DE, AB || DE, BC = EF and BC || EF. Vertices A, B and C are joined to vertices D, E and F respectively (see the given figure). Show that:

(1) Quadrilateral ABED is a parallelogram.

(2) Quadrilateral BEFC is a parallelogram.

(3) AD || CF and AD = CF

(4) Quadrilateral ACFD is a parallelogram.

(5) AC = DF

(6) ΔABC ≅ ΔDEF.

Answer:

(1) It is given that AB = DE and AB || DE.

If two opposite sides of a quadrilateral are equal and parallel to each other, then it will be a parallelogram.

Therefore, quadrilateral ABED is a parallelogram.

(2) Again, BC = EF and BC || EF

Therefore, quadrilateral BCEF is a parallelogram.

(3) As we had observed that ABED and BEFC are parallelograms, therefore AD = BE and AD || BE (Opposite sides of a parallelogram are equal and parallel)

And, BE = CF and BE || CF (Opposite sides of a parallelogram are equal and parallel)

So, AD = CF and AD || CF

(4) As we had observed that one pair of opposite sides (AD and CF) of quadrilateral ACFD are equal and parallel to each other, therefore, it is a parallelogram.

(5) As ACFD is a parallelogram, therefore, the pair of opposite sides will be equal and parallel to each other.

AC || DF and AC = DF

(6) ΔABC and ΔDEF,

AB = DE (Given)

BC = EF (Given)

AC = DF (ACFD is a parallelogram)

ΔABC ≅ ΔDEF (By SSS congruence rule)

Question 12: ABCD is a trapezium in which AB || CD and AD = BC (see the given figure). Show that:

(1) ∠A = ∠B

(2) ∠C = ∠D

(3) ΔABC ≅ ΔBAD

(4) diagonal AC = diagonal BD

[Hint: Extend AB and draw a line through C parallel to DA intersecting AB produced at E.]

Answer:

Let us extend AB. Then, draw a line through C, which is parallel to AD, intersecting AE at point E. It is clear that AECD is a parallelogram.

(1) AD = CE (Opposite sides of parallelogram AECD)

However, AD = BC (Given)

Therefore, BC = CE

Hence, ∠CEB = ∠CBE (Angle opposite to equal sides are also equal)

Consider parallel lines AD and CE.

AE is the transversal line for them.

∠A + ∠CEB = 180⁰ (Angles on the same side of transversal)

∠A + ∠CBE = 180⁰ (Using the relation ∠CEB = ∠CBE) …………….(1)

However, ∠B + ∠CBE = 180⁰ (Linear pair angles) ……………………….(2)

From equations (1) and (2), we obtain

∠A = ∠B

(2) AB || CD

∠A + ∠D = 180⁰ (Angles on the same side of the transversal)

Also, ∠C + ∠B = 180⁰ (Angles on the same side of the transversal)

=> ∠A + ∠D = ∠C + ∠B

However, ∠A = ∠B [Using the result obtained in (1)]

=> ∠C = ∠D

(3) In ΔABC and ΔBAD,

AB = BA (Common side)

BC = AD (Given)

∠B = ∠A (Proved before)

So, ΔABC ≅ ΔBAD (SAS congruence rule)

(4) We have observed that,

ΔABC ≅ ΔBAD.

So, AC = BD (By CPCT)

Exercise 8.2

Question 1: ABCD is a quadrilateral in which P, Q, R and S are mid-points of the sides AB, BC, CD and DA (see the given figure). AC is a diagonal. Show that:

(1) SR || AC and SR = AC/2

(2) PQ = SR

(3) PQRS is a parallelogram.

Answer:

(1) In ΔADC, S and R are the mid-points of sides AD and CD respectively.

In a triangle, the line segment joining the mid-points of any two sides of the triangle is parallel to the third side and is half of it.

So, SR || AC and SR = AC/2 ………………….(1)

(2) In ΔABC, P and Q are mid-points of sides AB and BC respectively.

Therefore, by using mid-point theorem,

PQ || AC and PQ = AC ……………….(2)

Using equations 1 and 2, we obtain

PQ || SR and PQ = SR …………………. (3)

So, PQ = SR

(3) From equation 3, we obtained PQ || SR and PQ = SR

Clearly, one pair of opposite sides of quadrilateral PQRS is parallel and equal.

Hence, PQRS is a parallelogram.

Question 2: ABCD is a rhombus and P, Q, R and S are the mid-points of the sides AB, BC, CD and DA respectively. Show that the quadrilateral PQRS is a rectangle.

Answer:

In ΔABC, P and Q are the mid-points of sides AB and BC respectively.

PQ || AC and PQ = AC/2 ……………………………………………………………… (1) (Using mid-point theorem)

In ΔADC,

R and S are the mid-points of CD and AD respectively.

RS || AC and RS = AC/2 ………………………………………………………………….. (2) (Using mid-point theorem)

From equations 1 and 2, we obtain

PQ || RS and PQ = RS

Since in quadrilateral PQRS, one pair of opposite sides is equal and parallel to each other, it is a parallelogram.

Let the diagonals of rhombus ABCD intersect each other at point O.

In quadrilateral OMQN,

MQ || ON (Since PQ || AC)

QN || OM (Since QR || BD)

Therefore, OMQN is a parallelogram.

∠MQN = ∠NOM

∠PQR = ∠NOM

However, ∠NOM = 90⁰ (Diagonals of a rhombus are perpendicular to each other)

So, ∠PQR = 90⁰

Clearly, PQRS is a parallelogram having one of its interior angles as 90⁰.

Hence, PQRS is a rectangle.

Question 3: ABCD is a rectangle and P, Q, R and S are mid-points of the sides AB, BC, CD and DA respectively. Show that the quadrilateral PQRS is a rhombus.

Answer:

Let us join AC and BD. In ΔABC,

P and Q are the mid-points of AB and BC respectively.

So, PQ || AC and PQ = AC/2 ……………………………………………….. (1) (Mid-point theorem)

Similarly, in ΔADC,

SR || AC and SR = AC/2 ………………………………………………………………………. (2) (Mid-point theorem)

Clearly, PQ || SR and PQ = SR

Since in quadrilateral PQRS, one pair of opposite sides is equal and parallel to each other, it is a parallelogram.

PS || QR and PS = QR ………………………………………………………………………….. (3) (Opposite sides of parallelogram)

In ΔBCD, Q and R are the mid-points of side BC and CD respectively.

QR || BD and QR = BD/2 ………………………………………………………………………. (4) (Mid-point theorem)

However, the diagonals of a rectangle are equal.

So, AC = BD …………… (5)

By using equation (1), (2), (3), (4), and (5), we obtain

PQ = QR = SR = PS

Therefore, PQRS is a rhombus.

Question 4: ABCD is a trapezium in which AB || DC, BD is a diagonal and E is the mid-point of AD. A line is drawn through E parallel to AB intersecting BC at F (see the given figure). Show that F is the mid-point of BC.

Answer:

Let EF intersect DB at G.

By converse of mid-point theorem, we know that a line drawn through the mid-point of any side of a triangle and parallel to another side, bisects the third side.

In ΔABD,

EF || AB and E is the mid-point of AD.

Therefore, G will be the mid-point of DB.

As EF || AB and AB || CD,

So, EF || CD (Two lines parallel to the same line are parallel to each other)

In ΔBCD, GF || CD and G is the mid-point of line BD.

Therefore, by using converse of mid-point theorem, F is the mid-point of BC.

Question 5: In a parallelogram ABCD, E and F are the mid-points of sides AB and CD respectively (see the given figure). Show that the line segments AF and EC trisect the diagonal BD.

Answer:

ABCD is a parallelogram.

So, AB || CD

And hence, AE || FC

Again, AB = CD (Opposite sides of parallelogram ABCD)

=> AB/2 = CD/2

=> AE = FC (E and F are mid-points of side AB and CD)

In quadrilateral AECF, one pair of opposite sides (AE and CF) is parallel and equal to each other.

Therefore, AECF is a parallelogram.

AF || EC (Opposite sides of a parallelogram)

In ΔDQC,

F is the mid-point of side DC and FP || CQ (As, AF || EC).

Therefore, by using the converse of mid-point theorem, it can be said that P is the mid-point of DQ.

So, DP = PQ ……………….(1)

Similarly, in ΔAPB,

E is the mid-point of side AB and EQ || AP (As, AF || EC).

Therefore, by using the converse of mid-point theorem, it can be said that Q is the mid-point of PB.

So, PQ = QB ……………….(2)

From equations (1) and (2),

DP = PQ = BQ

Hence, the line segments AF and EC trisect the diagonal BD.

Question 6: Show that the line segments joining the mid-points of the opposite sides of a quadrilateral bisect each other.

Answer:

Let ABCD is a quadrilateral in which P, Q, R, and S are the mid-points of sides AB, BC, CD, and DA respectively.

Join PQ, QR, RS, SP, and BD.

In ΔABD, S and P are the mid-points of AD and AB respectively.

Therefore, by using mid-point theorem, it can be said that

SP || BD and SP = BD/2 ……………………………………….(1)

Similarly, in ΔBCD,

QR || BD and QR = BD/2 …………………………………….(2)

From equations (1) and (2), we obtain

SP || QR and SP = QR

In quadrilateral SPQR, one pair of opposite sides is equal and parallel to each other.

Therefore, SPQR is a parallelogram.

We know that diagonals of a parallelogram bisect each other.

Hence, PR and QS bisect each other.

Question 7: ABC is a triangle right angled at C. A line through the mid-point M of hypotenuse AB and parallel to BC intersects AC at D. Show that:

(1) D is the mid-point of AC

(2) MD ⟂ AC

(3) CM = MA = AB/2

Answer:

(1) In ΔABC,

It is given that M is the mid-point of AB and MD || BC.

Therefore, D is the mid-point of AC. (Converse of mid-point theorem)

(2) As DM || CB and AC is a transversal line for them, therefore,

∠MDC + ∠DCB = 180⁰ (Co-interior angles)

=> ∠MDC + 90⁰ = 180⁰

=> ∠MDC = 90⁰

So, MD ⟂ AC

(3) Join MC.

In ΔAMD and ΔCMD,

AD = CD (D is the mid-point of side AC)

∠ADM = ∠CDM (Each 90⁰)

DM = DM (Common)

ΔAMD ≅ ΔCMD (By SAS congruence rule)

Therefore, AM = CM (By CPCT)

However, AM = AB/2 (Since M is the mid-point of AB)

Therefore, it can be said that

CM = AM = AB/2