Chapter 8 of 12

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IB Class 9 Mathematics★ 8–12 marks · CBSE Class 9 board

Quadrilaterals

Most shapes you'll ever draw are quadrilaterals — a screen, a door, a phone, a notebook. Class 9 chapter on parallelograms, rectangles, rhombuses, squares, trapezia, plus the Mid-Point Theorem — all proved using triangle congruence. 25+ exam-style problems with full step-by-step solutions.

⏱ 40 min readMedium difficulty✓ Free · NCERT-aligned

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By the end of this chapter you'll be able to…

1State and apply the Angle Sum Property of a quadrilateral (sum = 360°)
2Recognise the parallelogram family tree (parallelogram, rectangle, rhombus, square, trapezium)
3Prove and apply the four parallelogram properties (opposite sides/angles, diagonals, adjacent angles)
4Apply special properties of rectangles, rhombuses, squares (diagonal length/perpendicularity)
5Prove and apply the Mid-Point Theorem and its converse
6Use congruence (SSS, SAS, ASA, etc.) within quadrilateral proofs
7Identify which 'converse' tests qualify a quadrilateral as a parallelogram

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Why this chapter matters

Most shapes you'll ever model are quadrilaterals — screens, doors, brick walls, GIS tiles. The Mid-Point Theorem proved here is one of the most reusable tools in all of plane geometry.

Before you start — revise these

A 5-minute refresher here will save you 30 minutes of confusion below.

🔗

Triangles (Class 9, Ch 7)

Congruence criteria + CPCT

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Lines and Angles (Class 9, Ch 6)

Parallel-line angle theorems

Quadrilaterals — Class 9 (CBSE)

Look around. Almost every flat shape you see — your phone screen, this page, a door, a window, a brick, a road sign — is a quadrilateral. This chapter classifies them, proves their properties, and gives you the most useful tool in geometry: the Mid-Point Theorem.

1. The big picture — the family tree

                         QUADRILATERAL  (any 4-sided polygon)
                                  │
                       (one pair parallel sides)
                                  │
                              TRAPEZIUM
                                  │
                       (both pairs parallel sides)
                                  │
                          PARALLELOGRAM
                                  │
                ┌─────────────────┼─────────────────┐
        (all right angles)  (all sides equal)   (right angles + all sides equal)
                │                 │                   │
            RECTANGLE          RHOMBUS              SQUARE

A square is a rectangle that's also a rhombus. A rhombus is a parallelogram with all sides equal. A rectangle is a parallelogram with all angles 90°. A parallelogram is a quadrilateral with both pairs of opposite sides parallel. And a trapezium has only ONE pair of parallel sides.

Mastering this family tree saves you in every quadrilateral problem.

2. Angle sum of a quadrilateral

Theorem. The sum of the four interior angles of a quadrilateral is $360°$ .

Proof. Draw the diagonal $A C$ of quadrilateral $A B C D$ . It divides the quadrilateral into two triangles: $△ A B C$ and $△ A C D$ .

Angle sum of $△ A B C = 180°$ .
Angle sum of $△ A C D = 180°$ .
Total = $360°$ .

But the total of the two triangles' angles equals the sum of the four interior angles of $A B C D$ . ∎

Worked example. Three angles of a quadrilateral are 60°, 90° and 110°. Find the fourth.

$60° + 90° + 110° + ∠ D = 360° \Rightarrow ∠ D = 100°$ .

3. The Parallelogram — definition and properties

A parallelogram is a quadrilateral in which both pairs of opposite sides are parallel.

Theorem (P1). A diagonal of a parallelogram divides it into two CONGRUENT triangles.

Proof. In parallelogram $A B C D$ with diagonal $A C$ :

$A B ∥ D C$ ⇒ $∠ B A C = ∠ D C A$ (alternate interior angles).
$A D ∥ B C$ ⇒ $∠ A C B = ∠ C A D$ (alternate interior).
$A C = A C$ (common). By ASA: $△ A B C ≅ △ C D A$ . ∎

Theorem (P2). Opposite sides of a parallelogram are EQUAL. (Direct consequence of P1 + CPCT.)

Theorem (P3). Opposite angles of a parallelogram are EQUAL.

Theorem (P4). The diagonals BISECT each other.

Theorem (P5). Adjacent angles are SUPPLEMENTARY (sum to 180°).

Converse theorems — when is a quadrilateral a parallelogram?

Each of the following is a SUFFICIENT condition for a quadrilateral to be a parallelogram: (C1) Both pairs of opposite sides are equal. (C2) Both pairs of opposite angles are equal. (C3) Diagonals bisect each other. (C4) One pair of opposite sides is equal AND parallel.

4. Rectangles, rhombuses, squares

Each adds an extra constraint to the parallelogram:

Shape	Definition	Special properties (beyond ∥gram)
Rectangle	Parallelogram with one right angle (so all four are right)	Diagonals are EQUAL
Rhombus	Parallelogram with all four sides equal	Diagonals are PERPENDICULAR; diagonals BISECT the angles
Square	Both a rectangle and a rhombus	All rectangle properties + all rhombus properties

Key theorem. The diagonals of a rectangle are EQUAL. The diagonals of a rhombus are PERPENDICULAR and BISECT each other AT RIGHT ANGLES. The diagonals of a square are EQUAL, PERPENDICULAR, and bisect each other.

5. The Mid-Point Theorem — the chapter's crown jewel

Mid-Point Theorem. The line segment joining the midpoints of two sides of a triangle is parallel to the third side and half its length.

In $△ A B C$ , if $D$ is the midpoint of $A B$ and $E$ is the midpoint of $A C$ , then: $D E ∥ B C and D E = \frac{1}{2} B C .$

Why useful? Whenever you see midpoints connected, this theorem replaces a multi-step proof with one line.

Worked example. In $△ P QR$ , $S$ and $T$ are midpoints of $P Q$ and $P R$ . If $S T = 4$ cm, find $QR$ . By Mid-Point Theorem, $S T = (1/2) QR \Rightarrow QR = 2 S T = 8$ cm.

Converse

Converse of Mid-Point Theorem. The line drawn through the midpoint of one side of a triangle, parallel to the second side, bisects the third side.

So if $D$ is the midpoint of $A B$ and a line through $D$ parallel to $B C$ meets $A C$ at $E$ , then $E$ is the midpoint of $A C$ .

6. Trapezium

A trapezium has exactly one pair of parallel sides. (Some textbooks allow "at least one" — CBSE uses "exactly one.")

The parallel sides are called bases; the non-parallel sides are legs. The line joining the midpoints of the two legs is the mid-segment, and its length is the average of the two bases.

A trapezium with the two legs equal is isosceles.

7. Six worked exam examples

Example 1 — Angle sum (1 mark)

Three angles of a quadrilateral are 75°, 90° and 130°. Find the fourth. $75 + 90 + 130 = 295 \Rightarrow$ fourth $= 360 - 295 = 65°$ .

Example 2 — Parallelogram property (2 marks)

In parallelogram $A B C D$ , $∠ A = 60°$ . Find all four angles. Opposite angles equal: $∠ C = 60°$ . Adjacent supplementary: $∠ B = 180° - 60° = 120°$ , $∠ D = 120°$ .

Example 3 — Rhombus diagonals (2 marks)

A rhombus has diagonals 10 cm and 24 cm. Find each side. Diagonals of a rhombus bisect at right angles → each side is the hypotenuse of a right triangle with legs $5$ and $12$ . Side $= 5^{2} + 1 2^{2} = 25 + 144 = 169 = 13$ cm.

Example 4 — Rectangle diagonals (2 marks)

In rectangle $A B C D$ , diagonal $B D = 13$ cm and $A B = 5$ cm. Find $B C$ . By Pythagoras on $△ A B D$ (right-angled at $A$ ): $B D^{2} = A B^{2} + A D^{2} \Rightarrow 169 = 25 + A D^{2} \Rightarrow A D = 12$ cm. Hence $B C = A D = 12$ cm (opposite sides of rectangle).

Example 5 — Mid-Point Theorem (3 marks)

In $△ A B C$ , $P, Q, R$ are midpoints of $B C, C A, A B$ respectively. Show that $P QR S$ (with $S$ chosen appropriately) is... actually: show that $△ P QR ≅ △$ — but a simpler classic: Prove $△ P QR ≅ △ R B P$ in $△ A B C$ with $P, Q, R$ midpoints of $B C, C A, A B$ .

By Mid-Point Theorem applied three times:

$R Q ∥ B C$ and $R Q = (1/2) B C = B P$ (since $P$ is midpoint of $B C$ ). So $R Q = B P$ and $R Q ∥ B P$ .
Therefore $B P QR$ is a parallelogram (one pair equal AND parallel) → $P Q = B R$ and $∠ R B P = ∠ R QP$ .
Now in $△ P QR$ and $△ R B P$ : $P Q = R B$ , $QR = B P$ , $P R = P R$ → SSS congruence.

Example 6 — HOTS (4 marks)

Prove that the diagonals of a rhombus bisect each other at right angles. Let rhombus be $A B C D$ with diagonals $A C$ and $B D$ meeting at $O$ . Since a rhombus IS a parallelogram, $O$ bisects both diagonals. Now in $△ A O B$ and $△ A O D$ : $A B = A D$ (rhombus, all sides equal), $O B = O D$ (bisection), $O A = O A$ (common) → SSS → $△ A O B ≅ △ A O D$ . Hence $∠ A O B = ∠ A O D$ (CPCT). They form a linear pair on $B D$ , so each = 90°. ∎

8. Common pitfalls

Calling a rectangle a 'square'. A rectangle has 90° angles but unequal adjacent sides (in general). Only when all four sides are equal does it become a square.
Saying parallelogram diagonals are equal. They're EQUAL only in rectangles (and squares). In a generic parallelogram, diagonals bisect each other but are NOT equal.
Confusing 'parallelogram' with 'trapezium'. Parallelogram has TWO pairs parallel; trapezium has exactly ONE.
Forgetting Mid-Point Theorem requires midpoints. Don't apply it when the points aren't midpoints. Use the converse only when one midpoint + parallel is given.
Wrong angle relation. Adjacent angles in a parallelogram are SUPPLEMENTARY (180°), not 90°.
Rhombus and square confusion. All sides equal alone doesn't make a square — angles must be 90° too. A rhombus is "tilted square."

9. Beyond NCERT — stretch problems

Stretch 1 — Mid-segment of a trapezium

Prove that the line joining the midpoints of the two non-parallel sides of a trapezium is parallel to the bases and equals their half-sum. Hint: extend one leg into a triangle and apply the Mid-Point Theorem twice.

Stretch 2 — Varignon's Theorem

In any quadrilateral (not just parallelograms!), the midpoints of the four sides form a parallelogram. Proof: connect the midpoints; apply Mid-Point Theorem to the two triangles formed by a diagonal.

Stretch 3 — JEE-style

Show that the quadrilateral formed by joining the midpoints of the sides of a rectangle is a rhombus. Use Varignon + the property that the rectangle's diagonals are equal.

10. Real-world quadrilaterals

Doors and windows. Almost always rectangular for structural reasons and easy manufacture.
Tiles. Squares, rectangles, and parallelograms tile the plane perfectly. Hexagons and triangles do too — but pentagons don't.
Maps. Country borders rarely form perfect quadrilaterals, but city blocks (Manhattan-style) are mostly rectangles.
Bricks and lego. Bricks are 'cuboids' — 3D rectangles. Their face symmetry uses every quadrilateral property.
Diamond cuts. Rhombus-shaped facets reflect light to maximise sparkle.
Kite design. The aerodynamic 'kite' shape is a quadrilateral with two pairs of adjacent equal sides.

11. CBSE exam blueprint

Type	Marks	Typical question	Time
VSA	1	Angle sum; identify quadrilateral type	30 sec
SA-I	2	Parallelogram property; find missing angle	2 min
SA-II	3	Rhombus diagonals; rectangle diagonals; mid-segment	4–5 min
LA	4	Multi-step proof; Mid-Point Theorem application	6–8 min

Total marks: 8–12 / 80 in Class 9 finals. Mid-Point Theorem appears in 80% of papers — practise it thoroughly.

Three exam-day strategies:

Identify the quadrilateral type first (using the family tree). Each type has its own theorems.
The Mid-Point Theorem replaces multi-step proofs — always try it when you see midpoints.
For a rhombus / rectangle question, leverage diagonal properties (perpendicular bisectors / equal lengths).

12. NCERT exercise walkthrough

Exercise 8.1: 7 questions — basic parallelogram theorems and converses.
Exercise 8.2: 7 questions — Mid-Point Theorem and applications.

(Reduced from 8.1–8.4 in older NCERT.)

13. 60-second recap

Quadrilateral angle sum = 360°.
Parallelogram: both pairs of opposite sides parallel. Opposite sides/angles equal; adjacent angles supplementary; diagonals bisect each other.
Rectangle: parallelogram with 90° angles → diagonals equal.
Rhombus: parallelogram with all sides equal → diagonals perpendicular.
Square: rectangle + rhombus combined.
Trapezium: one pair of parallel sides.
Mid-Point Theorem: segment joining midpoints of two sides is parallel to and half the third side.
Converse: line through midpoint of one side, parallel to second side, hits midpoint of third.

Take the practice quiz and the flashcard deck. Next: Circles.

Key formulas & results

Everything you need to memorise, in one card. Screenshot this for revision.

Quadrilateral angle sum

∠A + ∠B + ∠C + ∠D = 360°

Proven by splitting into 2 triangles.

Parallelogram — opp. sides

AB = CD, AD = BC

Parallelogram — opp. angles

∠A = ∠C, ∠B = ∠D

Parallelogram — adj. angles

∠A + ∠B = 180° (etc.)

Supplementary.

Parallelogram — diagonals

Diagonals BISECT each other

Don't have to be equal.

Rectangle

Parallelogram + one right ∠ ⇒ diagonals EQUAL

Rhombus

Parallelogram + all sides equal ⇒ diagonals ⊥

Diagonals also bisect the angles.

Square

Rectangle + Rhombus → all properties combined

Equal AND perpendicular diagonals.

Mid-Point Theorem

DE ∥ BC and DE = BC/2

D, E midpoints of AB, AC in △ABC.

Converse MPT

Line through midpoint, parallel to side, bisects 3rd side

⚠️

Common mistakes & fixes

These are the exact errors that cost students marks in board exams. Read them once, save yourself the trouble.

WATCH OUT

✗ Calling every rectangle a square

✓ Square needs all sides equal too.

WATCH OUT

✗ Saying parallelogram diagonals are equal

✓ Only RECTANGLE diagonals are equal among parallelograms.

WATCH OUT

✗ Confusing trapezium with parallelogram

✓ Parallelogram = BOTH pairs parallel. Trapezium = ONE pair parallel.

WATCH OUT

✗ Applying Mid-Point Theorem with non-midpoints

✓ Only works when both endpoints are MIDPOINTS. Otherwise, use converse or different technique.

WATCH OUT

✗ Saying adjacent angles in a ∥gram are 90°

✓ Adjacent angles are SUPPLEMENTARY (sum to 180°), not necessarily 90°. They're 90° only in rectangles/squares.

NCERT exercises (with solutions)

Every NCERT exercise from this chapter — what it covers and how many questions to expect.

Ex 8.1

Exercise 8.1

Parallelogram properties, converses, simple problems

Questions

Ex 8.2

Exercise 8.2

Mid-Point Theorem and applications

Questions

Practice problems

Try each one yourself before tapping "Show solution". Active recall > rereading.

Q1EASY· Angle sum

Three angles of a quadrilateral are 80°, 100°, 110°. Find the fourth.

▶ Show solution

Step 1 — Apply the Quadrilateral Angle Sum Property.
  ∠A + ∠B + ∠C + ∠D = 360°.

Step 2 — Substitute known values.
  80° + 100° + 110° + ∠D = 360°.
  290° + ∠D = 360°.

Step 3 — Solve.
  ∠D = 70°.

✦ Answer: Fourth angle = 70°.

Q2EASY· Identify

Name the quadrilateral whose diagonals are equal AND bisect each other at right angles.

▶ Show solution

Step 1 — Diagonals bisect each other → parallelogram.

Step 2 — Diagonals are equal → among parallelograms, this is a rectangle.

Step 3 — Diagonals also perpendicular → it's also a rhombus.

Step 4 — A figure that is both a rectangle and a rhombus is a SQUARE.

✦ Answer: Square.

Q3EASY· Parallelogram

In parallelogram ABCD, ∠A = 75°. Find ∠C.

▶ Show solution

Step 1 — Opposite angles of a parallelogram are equal.

Step 2 — ∠C is opposite to ∠A.
  So ∠C = ∠A = 75°.

✦ Answer: ∠C = 75°.

Q4EASY· Parallelogram

In parallelogram ABCD, ∠A = 70°. Find ∠B.

▶ Show solution

Step 1 — Adjacent angles of a parallelogram are supplementary.

Step 2 — ∠A and ∠B are adjacent.
  ∠A + ∠B = 180° → 70° + ∠B = 180° → ∠B = 110°.

✦ Answer: ∠B = 110°.

Q5EASY· Mid-Point Theorem

In △ABC, D and E are midpoints of AB and AC respectively. If BC = 10 cm, find DE.

▶ Show solution

Step 1 — Apply Mid-Point Theorem.
  DE is parallel to BC and DE = BC/2.

Step 2 — Compute.
  DE = 10/2 = 5 cm.

✦ Answer: DE = 5 cm.

Q6MEDIUM· Rhombus diagonals

A rhombus has diagonals 16 cm and 30 cm. Find each side.

▶ Show solution

Step 1 — Rhombus diagonals bisect each other at right angles.
  So each diagonal is split into halves: 8 cm and 15 cm.

Step 2 — Half-diagonals form a right triangle with the side as hypotenuse.
  side² = 8² + 15² = 64 + 225 = 289.
  side = √289 = 17 cm.

✦ Answer: Each side of the rhombus = 17 cm.

Nice property: the half-diagonals (8, 15, 17) form a Pythagorean triple.

Q7MEDIUM· Rectangle

In rectangle ABCD, AC and BD are diagonals. If AC = 26 cm and AB = 10 cm, find BC.

▶ Show solution

Step 1 — Diagonal of rectangle = hypotenuse of right triangle with sides AB and BC.
  AC² = AB² + BC².

Step 2 — Substitute.
  26² = 10² + BC²
  676 = 100 + BC²
  BC² = 576 → BC = 24.

✦ Answer: BC = 24 cm.

Note: 10-24-26 is a Pythagorean triple (twice 5-12-13).

Q8MEDIUM· Parallelogram converse

In quadrilateral ABCD, AB = CD and AB ∥ CD. Show that ABCD is a parallelogram.

▶ Show solution

Step 1 — This is Converse C4: one pair of opposite sides EQUAL AND PARALLEL → parallelogram.

Step 2 — Draw diagonal AC. In △ABC and △CDA:
  AB = CD (given).
  AB ∥ CD ⇒ ∠BAC = ∠DCA (alternate interior).
  AC = AC (common).

Step 3 — By SAS, △ABC ≅ △CDA.

Step 4 — By CPCT, BC = AD AND ∠BCA = ∠DAC.
  ∠BCA = ∠DAC are alternate interior angles for lines AD and BC with transversal AC. So AD ∥ BC.

Step 5 — Both pairs of opposite sides are parallel ⇒ ABCD is a parallelogram. ∎

✦ Answer: ABCD is a parallelogram by the converse criterion.

Q9MEDIUM· Mid-Point app

In △ABC, P, Q, R are midpoints of BC, CA, AB respectively. Show that PQRS (where S is... actually a simpler version) — Show that △PQR has each side equal to half of one side of △ABC.

▶ Show solution

Step 1 — Apply Mid-Point Theorem to each pair.
  In △ABC with P, Q midpoints of BC, CA: PQ ∥ AB and PQ = AB/2.
  Similarly QR ∥ BC and QR = BC/2.
  Similarly RP ∥ CA and RP = CA/2.

Step 2 — Conclude.
  Each side of △PQR equals half the parallel side of △ABC.

✦ Answer: Each side of △PQR = half the corresponding side of △ABC.

Corollary: △PQR is similar to △ABC with ratio 1:2 (Class 10 concept). Its perimeter is half of △ABC's; its area is 1/4 of △ABC's.

Q10HARD· HOTS — rhombus

Prove that the diagonals of a rhombus bisect each other at right angles.

▶ Show solution

Step 1 — Setup. Rhombus ABCD with diagonals AC, BD meeting at O.

Step 2 — Since ABCD is a (special) parallelogram, the diagonals bisect each other (parallelogram property). So OA = OC and OB = OD.

Step 3 — Compare △AOB and △AOD.
  AB = AD (rhombus — all sides equal).
  OB = OD (Step 2).
  OA = OA (common).

Step 4 — By SSS, △AOB ≅ △AOD.

Step 5 — By CPCT, ∠AOB = ∠AOD.

Step 6 — ∠AOB + ∠AOD = 180° (linear pair on line BD).
  Combining with Step 5: 2·∠AOB = 180° → ∠AOB = 90°.

Step 7 — Therefore the diagonals meet at right angles AND bisect each other. ∎

✦ Answer: Diagonals of a rhombus bisect each other at right angles.

Q11HARD· HOTS — converse MPT

In △PQR, S is the midpoint of PQ. A line through S parallel to QR meets PR at T. Prove that T is the midpoint of PR.

▶ Show solution

Step 1 — Setup. S midpoint of PQ; ST ∥ QR, T on PR.

Step 2 — Apply the Converse of the Mid-Point Theorem.
  Statement: a line drawn through the midpoint of one side, parallel to the second side, bisects the third side.

Step 3 — In our case:
  S is midpoint of side PQ ✓.
  Line ST is parallel to side QR ✓.
  Line ST meets side PR at T.
  By the Converse MPT, T is the midpoint of PR. ∎

✦ Answer: T is the midpoint of PR.

Length bonus: ST = QR / 2 (by Mid-Point Theorem applied to the now-known midpoints S, T).

Q12HARD· Varignon — HOTS

Prove: in any quadrilateral, the midpoints of the four sides form a parallelogram.

▶ Show solution

Step 1 — Setup. Quadrilateral ABCD. Let P, Q, R, S be the midpoints of AB, BC, CD, DA respectively.

Step 2 — Draw diagonal AC. Now △ABC and △ACD share AC.

Step 3 — In △ABC, P and Q are midpoints of AB and BC.
  By Mid-Point Theorem: PQ ∥ AC and PQ = AC/2.

Step 4 — In △ACD, S and R are midpoints of AD and CD.
  By Mid-Point Theorem: SR ∥ AC and SR = AC/2.

Step 5 — Combine.
  PQ and SR are both parallel to AC AND both equal to AC/2.
  So PQ ∥ SR AND PQ = SR.

Step 6 — One pair of opposite sides of PQRS is equal AND parallel → PQRS is a parallelogram (Converse C4). ∎

✦ Answer: PQRS is a parallelogram. (This is Varignon's Theorem.)

This works for ANY quadrilateral — convex, concave, or even self-intersecting (though the resulting 'parallelogram' may be degenerate in special cases).

5-minute revision

The whole chapter, distilled. Read this the night before the exam.

•Quadrilateral angle sum = 360°.
•Parallelogram = both pairs parallel; opposite sides/angles equal; diagonals bisect.
•Rectangle = ∥gram with right angles → diagonals equal.
•Rhombus = ∥gram with all sides equal → diagonals perpendicular.
•Square = rectangle + rhombus.
•Trapezium = one pair parallel.
•Mid-Point Theorem: midpoints joined → parallel and half the 3rd side.
•Converse MPT: midpoint + parallel ⇒ bisects 3rd side.
•4 converses for parallelogram: opp. sides equal / opp. angles equal / diagonals bisect / one pair equal+parallel.

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Questions students ask

The real ones — pulled from the Q&A community and tutor sessions.

Yes — every rectangle satisfies the parallelogram definition (both pairs of opposite sides parallel). A rectangle is a SPECIAL parallelogram.

No — a rhombus has all sides equal but the angles aren't necessarily 90°. A 'tilted square' is a rhombus but not a square. Every square IS a rhombus.

Generally no — a trapezium has only ONE pair of parallel sides. If both pairs are parallel, it's a parallelogram, not a trapezium. (Some texts allow trapezium to mean 'at least one pair' — but CBSE uses 'exactly one'.)

It's a special case of similar triangles (Class 10). △ADE ~ △ABC with ratio 1:2, so DE is parallel to BC and half the length.

A quadrilateral with TWO pairs of CONSECUTIVE sides equal (not opposite). Diagonals are perpendicular but only ONE bisects the other. Not in CBSE syllabus formally, but appears in HOTS.

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