Ch-5 I’m Up and Down, and Round and Round class 9th maths ganita manjari ncert solution

May 27, 2026 • Admin ETeam • Class 9 NCERT Solution

Ch. 5 Solutions · Ganita Manjari · Class IX

NCERT · Ganita Manjari · Class IX · Part I

Chapter 5
I’m Up and Down,
and Round and Round

A complete, interactive companion — step-by-step solutions to every question in the chapter.

55+ Questions 10 Sections Visual Proofs

Choose an Exercise

Section 5.2

Think and Reflect — Symmetries of a Circle

3 questions

What are the rotational symmetries of a square? How many lines of reflection symmetry does it have? What about a regular pentagon? A regular hexagon?

A regular polygon with n sides has n rotational symmetries and n lines of reflection symmetry.

Square (n = 4): Rotations by 90°, 180°, 270°, 360°. Lines of reflection: 2 diagonals + 2 perpendicular bisectors of sides.

Square: 4 axes

Pentagon: 5 axes

Hexagon: 6 axes

Regular Pentagon (n = 5): 5 rotational symmetries (multiples of 72°), 5 lines of reflection.

Regular Hexagon (n = 6): 6 rotational symmetries (multiples of 60°), 6 lines of reflection.

Square: 4 rot, 4 lines · Pentagon: 5, 5 · Hexagon: 6, 6

What is the length of the longest chord in a circle of radius 5 units? Is there a smallest chord?

The longest chord is the diameter: $\text{Longest} = 2r = 2 \times 5 = 10 \text{ units}$.

For the smallest chord — as a chord shrinks to a single point on the circle, its length approaches 0 but never quite reaches 0. So there is no smallest chord.

Diameter = longest chord

Longest = 10 units · No smallest chord

What can we say about the locus of points equidistant from two given points?

The locus is the perpendicular bisector of segment AB.

Proof: If P lies on the perpendicular bisector through midpoint M, then in $\triangle PMA$ and $\triangle PMB$: $AM = BM$, $PM$ common, $\angle PMA = \angle PMB = 90°$. By SAS, $\triangle PMA \cong \triangle PMB$, so $PA = PB$.

Conversely, every point with $PA = PB$ lies on this line.

Perpendicular bisector of AB

The perpendicular bisector of segment AB

Section 5.3

Think and Reflect — How Many Circles?

5 questions

How many circles pass through two points on a plane?

The centre of any such circle must be equidistant from A and B, so it must lie on the perpendicular bisector of AB.

Since the perpendicular bisector has infinitely many points, we can draw a circle for each — giving infinitely many circles.

Infinitely many circles

What is the radius of the smallest and largest circle passing through A and B?

Smallest: Take midpoint of AB as centre — then AB is the diameter. Any smaller circle cannot enclose both A and B.

$r_{\min} = \dfrac{AB}{2}$

Largest: As the centre moves farther along the perpendicular bisector, the radius grows without bound — there is no largest circle.

Smallest radius = AB/2 · No largest radius

As you move away from segment AB along its perpendicular bisector, do the radii increase or decrease?

If O lies on the perpendicular bisector at distance $d$ from midpoint M, then by Pythagoras:

$OA = \sqrt{d^2 + \left(\tfrac{AB}{2}\right)^2}$

As $d$ increases, $OA$ (the radius) also increases.

The radii increase

As you move along the perpendicular bisector, will the circle through A and B appear more or less curved?

“More curved” = smaller radius (tighter turn); “less curved” = larger radius (flatter).

Since the radius grows as we move away (Q3), the circle becomes flatter — less curved.

Less curved (flatter)

Given two points A and B, how many squares can be drawn (a) with A and B on the boundary, (b) with A and B as corners?

(a) On the boundary: A and B can be anywhere on any side of a square — many orientations and sizes are possible. Hence infinitely many squares.

(b) As corners of the square:

If AB is a side of the square: 2 squares (one on each side of AB).
If AB is the diagonal: 1 square (uniquely determined).

Total: $2 + 1 = 3$ squares.

3 squares (2 with AB as side + 1 as diagonal)

On boundary: infinitely many · As corners: 3 squares

Exercise Set 5.1

Circumcircles & Three Points

4 + 2 questions

Draw △ABC with AB = 5 cm, ∠A = 70° and ∠B = 60°. Draw the circumcircle. Is the centre inside or outside?

$\angle C = 180° – 70° – 60° = 50°$

All three angles are less than 90° — so △ABC is acute-angled.

For acute triangles, the circumcentre lies inside the triangle.

Acute △ — O is inside

Inside the triangle

Draw △ABC with AB = 5 cm, ∠A = 100°, AC = 4 cm. Is the centre inside or outside?

$\angle A = 100° > 90°$ — so △ABC is obtuse-angled at A.

For obtuse triangles, the circumcentre lies outside the triangle, on the side opposite to the obtuse angle.

Obtuse △ — O is outside

Outside the triangle

Draw △ABC with AB = 6 cm, BC = 7 cm, CA = 7 cm. Find OA, OB, OC.

O is the circumcentre, so $OA = OB = OC = R$ (the circumradius).

Using Heron’s formula with $s = 10$:

$\text{Area} = \sqrt{10 \cdot 3 \cdot 3 \cdot 4} = \sqrt{360} = 6\sqrt{10}$

$R = \dfrac{abc}{4 \cdot \text{Area}} = \dfrac{7 \times 7 \times 6}{4 \times 6\sqrt{10}} = \dfrac{49}{4\sqrt{10}} \approx 3.87 \text{ cm}$

OA = OB = OC ≈ 3.87 cm

What is the least possible radius of a circle through two points A and B?

The smallest such circle has AB as its diameter — centre at the midpoint of AB.

$r_{\min} = \dfrac{AB}{2}$

Least radius = AB/2

Think, Draw and Infer

A, B, C are three collinear points. Can you find P with PA = PB = PC? Are the perpendicular bisectors of AB and BC parallel? Can a circle pass through collinear points?

If $PA = PB$, then P lies on the perpendicular bisector of AB. If $PB = PC$, then P lies on perpendicular bisector of BC.

Both A, B, C lie on the same line $\ell$. So both perpendicular bisectors are perpendicular to $\ell$ — making them parallel (they pass through different midpoints, so they never meet).

Hence no such P exists. So no circle passes through 3 collinear points. A line can intersect a circle in at most 2 points.

Perpendicular bisectors are parallel

No such P; bisectors are parallel; no circle through 3 collinear points

Can other triangles congruent to △ABC share the same circumcircle?

Yes! Rotate △ABC about the circumcentre O by any angle. The rotated triangle is congruent to the original and has the same circumcircle (rotation preserves circles through O).

Yes — infinitely many such triangles by rotation

Exercise Set 5.2

Triangles Formed by Chords

2 questions

Show that the triangle formed by a chord and the centre of a circle is isosceles.

Let AB be any chord of a circle with centre O. Join OA and OB.

Since OA and OB are both radii: $OA = OB = r$.

A triangle with two equal sides is isosceles, so △OAB is isosceles. $\blacksquare$

OA = OB = radius

OA = OB = r ⇒ △OAB is isosceles

Show that if two such isosceles triangles have equal base lengths, they are congruent.

Let △OAB and △OCD be two such triangles in the same circle, with $AB = CD$.

$OA = OC = r$ (radii)
$OB = OD = r$ (radii)
$AB = CD$ (given)

By the SSS congruence criterion: $\triangle OAB \cong \triangle OCD$. $\blacksquare$

By SSS: △OAB ≅ △OCD

Exercise Set 5.3

Perpendicular Bisectors of Chords

3 questions

Explain why the perpendicular from the centre to a chord bisects the chord.

Let C be the centre, AB the chord, and CM ⊥ AB with M on AB.

In △CMA and △CMB:

$CA = CB = r$ (radii — hypotenuses)
$CM = CM$ (common side)
$\angle CMA = \angle CMB = 90°$

By RHS congruence: $\triangle CMA \cong \triangle CMB$, hence $AM = BM$. $\blacksquare$

CM ⊥ AB ⇒ AM = BM

By RHS, △CMA ≅ △CMB ⇒ chord is bisected

Isosceles △ABC inscribed in a circle with AB = AC. Show that the altitude from A passes through the centre.

In an isosceles triangle, the altitude from the apex (A) is also the perpendicular bisector of the base BC.

By Theorem 5, the perpendicular bisector of any chord passes through the centre O of the circle.

Since BC is a chord and AD (the altitude) is its perpendicular bisector, AD passes through O. $\blacksquare$

Altitude from A = perpendicular bisector of BC ⇒ passes through O

Two parallel chords of lengths 6 cm and 8 cm are on opposite sides of the centre. Radius = 5 cm. Find the distance between the midpoints of the chords.

For chord 6 cm (half = 3): $d_1 = \sqrt{5^2 – 3^2} = \sqrt{16} = 4$ cm

For chord 8 cm (half = 4): $d_2 = \sqrt{5^2 – 4^2} = \sqrt{9} = 3$ cm

Since chords are on opposite sides of the centre, total distance:

$d_1 + d_2 = 4 + 3 = 7 \text{ cm}$

Opposite sides: 4 + 3 = 7 cm

Distance between midpoints = 7 cm

Exercise Set 5.4

Equal Chords & Pythagoras

3 questions

Use the Baudhāyana–Pythagoras theorem to prove Theorem 6 (equal chords are equidistant from the centre).

Let AB and FG be equal chords. Let E, H be midpoints of AB, FG respectively, with C the centre.

Since AB = FG and E, H are midpoints: $AE = FH$.

$CA = CF = r$ (radii). Apply Pythagoras in right triangles CEA and CHF:

$CE^2 = CA^2 – AE^2 = r^2 – AE^2$

$CH^2 = CF^2 – FH^2 = r^2 – FH^2$

Since $AE = FH$: $CE^2 = CH^2 \Rightarrow CE = CH$. $\blacksquare$

By Pythagoras: CE = CH ⇒ equal chords equidistant

If CE ⊥ AB, CH ⊥ GF, and CE = CH, show that AB = GF.

In right triangles CEA and CHF:

$\angle CEA = \angle CHF = 90°$
$CA = CF = r$ (hypotenuses)
$CE = CH$ (given)

By RHS: $\triangle CEA \cong \triangle CHF$ ⇒ $AE = FH$.

By Theorem 5, E and H are midpoints, so $AB = 2AE = 2FH = GF$. $\blacksquare$

CE = CH ⇒ AB = GF

By RHS congruence, AB = GF

Solve Q2 using the Baudhāyana–Pythagoras theorem.

Apply Pythagoras in △CEA and △CHF:

$AE^2 = CA^2 – CE^2 = r^2 – CE^2$

$FH^2 = CF^2 – CH^2 = r^2 – CH^2$

Given $CE = CH$: $AE^2 = FH^2$ ⇒ $AE = FH$.

So $AB = 2AE = 2FH = GF$. $\blacksquare$

By Pythagoras: AE = FH ⇒ AB = GF

Exercise Set 5.5

Distance of Chords from the Centre

3 questions

Find the length of a chord, where radius = 7 cm and perpendicular distance = 6 cm.

Using $\text{Chord} = 2\sqrt{r^2 – d^2}$:

$= 2\sqrt{7^2 – 6^2} = 2\sqrt{49 – 36} = 2\sqrt{13} \approx 7.21 \text{ cm}$

r = 7, d = 6

Chord length = 2√13 ≈ 7.21 cm

Prove: if perpendicular distance from centre is d and radius is r, the chord length is 2√(r² − d²).

Let AB be the chord, O the centre, M the foot of perpendicular from O to AB. By Theorem 5, M is the midpoint of AB.

△OMA is right-angled at M with $OA = r$ (hypotenuse), $OM = d$.

By Pythagoras:

$OA^2 = OM^2 + AM^2$

$AM = \sqrt{r^2 – d^2}$

Since M is the midpoint: $AB = 2 \cdot AM = 2\sqrt{r^2 – d^2}$. $\blacksquare$

Chord = 2√(r² − d²)

If distance of chord AB from centre is twice the distance of CD, can we conclude CD = 2 AB?

No. Let distance of CD be $d$, so distance of AB is $2d$. Then:

$AB = 2\sqrt{r^2 – 4d^2}, \quad CD = 2\sqrt{r^2 – d^2}$

For $CD = 2 \cdot AB$ we would need $r^2 – d^2 = 4(r^2 – 4d^2)$, giving $r^2 = 5d^2$ — only a special case, not general.

Counter-example: $r = 5, d = 1$:

$AB = 2\sqrt{21} \approx 9.17$, $CD = 2\sqrt{24} \approx 9.80$ — clearly $CD \neq 2 AB$.

No — the relationship is not linear (involves r²)

Exercise Set 5.6

Angles Subtended by Arcs

3 questions

In a circle with centre O, ∠AOB = 60°. If radius = 12 cm, find the length of chord AB.

△AOB has $OA = OB = 12$ cm and $\angle AOB = 60°$.

Base angles: $\angle OAB = \angle OBA = \dfrac{180° – 60°}{2} = 60°$.

All three angles are 60° → △AOB is equilateral.

$AB = OA = 12 \text{ cm}$

Equilateral △AOB ⇒ AB = 12

Chord AB = 12 cm

Let A and B be on a circle with centre O. (i) Can two points X, Y on the same side give ∠AXB ≠ ∠AYB? (ii) If ∠AXB = ∠AYB, must X, Y be on the same side? (iii) If ∠AXB = ∠AYB and X, Y are not on the circle, does the circle through A, B, X also pass through Y?

(i) No. By Theorem 9 (corollary), all points on the same arc subtend equal angles at chord AB. So $\angle AXB = \angle AYB$ always.

(ii) Not necessarily. If AB is a diameter, then any point on either arc gives 90°. So X, Y can lie on opposite arcs and still both equal 90°.

(iii) Yes. By Theorem 10, if AB subtends equal angles at two points on the same side, the four points are concyclic. So Y lies on the circle through A, B, X.

(i) No · (ii) Not necessarily · (iii) Yes

Find x in the figure (cyclic quadrilateral with opposite angles 100° and x).

In a cyclic quadrilateral, opposite angles sum to 180° (Theorem 11):

$100° + x = 180° \Rightarrow x = 80°$

Opposite angles: 100° + x = 180°

x = 80°

End-of-Chapter

Mixed Exercises

26 questions

A chord is 5 cm from the centre. Radius = 13 cm. Find the chord length.

$\text{Chord} = 2\sqrt{r^2 – d^2} = 2\sqrt{169 – 25} = 2\sqrt{144} = 24 \text{ cm}$

r = 13, d = 5 ⇒ chord = 24

Chord length = 24 cm

An arc subtends an angle of 70° at the centre. What is the angle at a point on the circle (outside the arc)?

By Theorem 9: the angle at the centre is double the angle at any point on the circle (outside the arc).

$\text{Angle at point} = \dfrac{70°}{2} = 35°$

35°

Diameter = 26 cm. A chord of length 24 cm is drawn. Find its distance from the centre.

Radius $r = 13$ cm. Half-chord = 12 cm.

$d = \sqrt{r^2 – (\text{chord}/2)^2} = \sqrt{169 – 144} = \sqrt{25} = 5 \text{ cm}$

Distance = 5 cm

Radius = 15 cm, distance from centre to chord = 9 cm. Find the chord length.

$\text{Chord} = 2\sqrt{15^2 – 9^2} = 2\sqrt{225 – 81} = 2\sqrt{144} = 24 \text{ cm}$

Chord = 24 cm

Prove that the perpendicular bisector of a chord passes through the centre.

Let AB be a chord, O the centre. Then $OA = OB = r$ (both radii).

Since O is equidistant from A and B, by the locus property of perpendicular bisectors, O lies on the perpendicular bisector of AB.

Hence the perpendicular bisector of AB passes through O. $\blacksquare$

OA = OB ⇒ O on perpendicular bisector

Diameter is AB. Point C is on the circumference. Find ∠ACB.

Centre O is midpoint of AB, so $OA = OB = OC = r$.

△OAC is isosceles: $\angle OAC = \angle OCA = \alpha$.

△OBC is isosceles: $\angle OBC = \angle OCB = \beta$.

In △ABC: $\alpha + \beta + \angle ACB = 180°$ and $\angle ACB = \alpha + \beta$.

So $2\angle ACB = 180°$ ⇒ $\angle ACB = 90°$.

Angle in semicircle = 90°

∠ACB = 90° (angle in semicircle)

In cyclic quadrilateral ABCD, ∠A = 75°. Find ∠C. If ∠B = 110°, find ∠D.

Opposite angles in cyclic quadrilateral sum to 180°:

$\angle C = 180° – 75° = 105°$

$\angle D = 180° – 110° = 70°$

∠C = 105°, ∠D = 70°

Cyclic quadrilateral PQRS with ∠P = (2x + 10)° and ∠R = (3x − 20)°. Find x, ∠P, ∠R.

∠P and ∠R are opposite angles:

$(2x + 10) + (3x – 20) = 180$

$5x – 10 = 180 \Rightarrow x = 38$

$\angle P = 2(38) + 10 = 86°$, $\angle R = 3(38) – 20 = 94°$. Check: $86° + 94° = 180°$ ✓

x = 38, ∠P = 86°, ∠R = 94°

A chord of length 16 cm is at distance 6 cm from the centre. Find the radius.

Half-chord = 8. By Pythagoras:

$r^2 = d^2 + 8^2 = 36 + 64 = 100 \Rightarrow r = 10 \text{ cm}$

Radius = 10 cm

A cyclic quadrilateral has sides 5, 5, 12, 12. Find its area.

Use Brahmagupta’s formula with semi-perimeter $s = \dfrac{5+5+12+12}{2} = 17$:

$\text{Area} = \sqrt{(s-a)(s-b)(s-c)(s-d)}$

$= \sqrt{12 \cdot 12 \cdot 5 \cdot 5} = \sqrt{3600} = 60$

Sides 5, 5, 12, 12

Area = 60 square units

Without drawing the circumcircle of a cyclic quadrilateral, how do we find out whether the circumcentre lies inside or outside?

Since opposite angles of a cyclic quadrilateral sum to 180°, either all four are 90° (rectangle) or two are obtuse and two are acute.

Rectangle/square: The diagonals are diameters, so the centre is at the intersection of the diagonals — clearly inside.
One diagonal subtends 90°: That diagonal is a diameter, so the centre lies on it (at its midpoint). The centre is inside if that midpoint lies inside the quadrilateral.
General case: Find the centre as the intersection of the perpendicular bisectors of any two sides — then check by inspection whether it lies inside the quadrilateral.

Quick rule: The centre lies inside iff every side (as a chord) has the rest of the quadrilateral on the side of its major arc.

Use intersection of perpendicular bisectors of two sides; check position

If two intersecting chords are of equal length, show that the line segments of one chord equal the corresponding segments of the other.

Let chords AB and CD intersect at P, with $AB = CD$. Drop perpendiculars OM, ON from centre O to AB, CD.

By Theorem 5: M, N are midpoints. By Theorem 6: $OM = ON$ (equal chords are equidistant).

In right triangles OMP and ONP:

$OM = ON$
$OP$ common
$\angle OMP = \angle ONP = 90°$

By RHS: $\triangle OMP \cong \triangle ONP \Rightarrow MP = NP$.

Since $AM = BM = CN = DN = AB/2$, the segments $AP, BP$ are $AM \pm MP$ and $CP, DP$ are $CN \pm NP$. With $AM = CN$ and $MP = NP$, the pairs match. $\blacksquare$

By RHS: MP = NP ⇒ segments match in pairs

Draw a circle in which a chord of 6 cm length is at distance 3 cm from the centre.

First find the radius:

$r = \sqrt{d^2 + (\text{chord}/2)^2} = \sqrt{9 + 9} = \sqrt{18} = 3\sqrt{2} \approx 4.24 \text{ cm}$

Construction:

Draw chord AB of length 6 cm.
Construct perpendicular bisector of AB; let it meet AB at M.
Mark point O on this bisector at distance 3 cm from M.
With O as centre, OA as radius, draw the circle.

r = 3√2 ≈ 4.24 cm

Radius = 3√2 ≈ 4.24 cm

Show that a rectangle is the only parallelogram that can be inscribed in a circle.

Let parallelogram ABCD be cyclic (inscribed in a circle).

Cyclic ⇒ $\angle A + \angle C = 180°$.

Parallelogram ⇒ $\angle A = \angle C$ (opposite angles equal).

So $2\angle A = 180°$ ⇒ $\angle A = 90°$. Similarly all four angles are 90°.

Hence ABCD is a rectangle. $\blacksquare$

All angles = 90° ⇒ rectangle

Show that the diagonals of a rectangle inscribed in a circle meet at the centre.

Since $\angle B = 90°$ and $\angle B$ is inscribed in the circle subtending chord AC: by the converse of “angle in semicircle = 90°”, AC must be a diameter.

Similarly, BD is also a diameter (since $\angle A = 90°$ subtends BD).

Two diameters of a circle both pass through the centre, so their intersection is the centre. $\blacksquare$

Diagonals = diameters ⇒ meet at O

Diagonals are diameters; intersect at the centre

Consider all chords of fixed length in a circle. What shape do their midpoints form?

For a chord of length $2\ell$ in a circle of radius $r$, the midpoint M satisfies $OM = \sqrt{r^2 – \ell^2}$ — a fixed distance.

So all midpoints lie at the same distance from O — they form a concentric circle of radius $\sqrt{r^2 – \ell^2}$.

Midpoints lie on a concentric circle

A concentric circle of radius √(r² − ℓ²)

In a circle with centre O, chords AB and AC are congruent. Show that O lies on the angle bisector of ∠BAC.

Since $AB = AC$ (equal chords), by Theorem 6, they are equidistant from O.

So the perpendicular distance from O to line AB equals the perpendicular distance from O to line AC.

A point equidistant from the two sides of an angle lies on its bisector.

Hence O lies on the bisector of $\angle BAC$. $\blacksquare$

O equidistant from AB and AC ⇒ on bisector of ∠BAC

Two parallel chords of lengths 10 cm and 24 cm are on the same side of the centre, 7 cm apart. Find the radius.

Let radius = $r$. Distances:

$d_1 = \sqrt{r^2 – 25}$ (10 cm chord), $d_2 = \sqrt{r^2 – 144}$ (24 cm chord)

Same side, gap = 7: $d_1 – d_2 = 7$.

Let $a = d_1, b = d_2$. Then $a – b = 7$, and $a^2 – b^2 = 119$.

$(a-b)(a+b) = 119 \Rightarrow a + b = 17$. Solving: $a = 12, b = 5$.

$r^2 = a^2 + 25 = 144 + 25 = 169 \Rightarrow r = 13 \text{ cm}$

Both on same side, 7 cm apart

Radius = 13 cm

A regular hexagon is inscribed in a circle of radius r. Find the side length and distance of each side from the centre.

Join O to two adjacent vertices A, B. △OAB has $OA = OB = r$ and $\angle AOB = 360°/6 = 60°$.

Base angles: $(180°-60°)/2 = 60°$. All angles are 60° ⇒ △OAB is equilateral.

So side $AB = r$. Distance from O to AB = height of equilateral triangle:

$\text{Distance} = \dfrac{\sqrt{3}}{2}\,r$

Side = r, apothem = r√3/2

Side = r · Distance from centre = r√3 / 2

Quadrilateral MNOP is inscribed in a circle. MN is a diameter. What can you say about ∠MOP and ∠MNP?

In cyclic quadrilateral MNOP, both N and O lie on the same arc with respect to chord MP. By the property “angles in the same segment are equal”:

$\angle MOP = \angle MNP$

Additionally, since MN is a diameter, $\angle MPN = 90°$ (angle in a semicircle).

∠MOP = ∠MNP (angles in same segment of chord MP)

In cyclic quadrilateral ABCD, prove that the exterior angle at any vertex equals the interior opposite angle.

Extend CD beyond D to a point E. The exterior angle at D is $\angle ADE$.

Linear pair: $\angle ADC + \angle ADE = 180°$ … (i)

Cyclic property: $\angle ADC + \angle ABC = 180°$ … (ii)

Subtracting: $\angle ADE = \angle ABC$. $\blacksquare$

Exterior angle = interior opposite angle (via linear pair + cyclic)

Justify: “No chord of a circle is longer than its diameter.”

Let AB be any chord, O the centre with radius $r$.

By the triangle inequality on points O, A, B:

$AB \le OA + OB = r + r = 2r = \text{diameter}$

Equality holds iff O lies on segment AB — i.e., AB is a diameter. $\blacksquare$

By triangle inequality: AB ≤ OA + OB = 2r

A is inside a circle with centre O. Show that the shortest chord through A is perpendicular to OA.

Any chord through A has midpoint M with $OM \perp$ chord (Theorem 4). Chord length:

$\text{chord} = 2\sqrt{r^2 – OM^2}$

To minimise chord, maximise $OM$.

For any chord through A: $OM \le OA$ (perpendicular is the shortest distance).

Equality holds when $M = A$ ⇒ $OA \perp$ chord. So the shortest chord is perpendicular to OA. $\blacksquare$

Shortest chord ⊥ OA

Shortest chord through A is perpendicular to OA

Use Fig. 5.30 to justify that the angle in a semicircle is 90°.

In the figure, O is the midpoint of the diameter, and A is on the semicircle. Join OA. Since OA, OB, OC are all radii:

△OAB is isosceles ⇒ base angles at A (left part) and at B both equal $a$.
△OAC is isosceles ⇒ base angles at A (right part) and at C both equal $b$.

Sum of triangle angles: $a + b + \angle A = 180°$. But $\angle A = a + b$.

$\Rightarrow 2(a+b) = 180° \Rightarrow a + b = 90°$

So $\angle A = 90°$. $\blacksquare$

a + b = 90° ⇒ ∠A = 90°

a + b = 90° ⇒ angle in semicircle = 90°

Two chords CC′ and DD′ are perpendicular to diameter AB. Prove MM′ (midpoints of CD and C′D′) is perpendicular to AB.

Since CC′ ⊥ diameter AB, by Theorem 5, AB bisects CC′ — so C and C′ are mirror images across AB.

Similarly, D and D′ are mirror images across AB.

Therefore segment CD is the reflection of segment C′D′ across AB. The midpoint M of CD reflects to the midpoint M′ of C′D′.

The line joining a point and its mirror image (across a line) is always perpendicular to that line.

Hence MM′ ⊥ AB. $\blacksquare$

M and M′ are mirror images across AB ⇒ MM′ ⊥ AB

Use Fig. 5.31 to justify that opposite angles of a cyclic quadrilateral sum to 180°.

O is joined to all four vertices, creating four isosceles triangles (two sides = radius).

Label base angles: $\alpha$ in △OAB, $\beta$ in △OBC, $\gamma$ in △OCD, $\delta$ in △ODA.

Interior angles of quadrilateral:

$\angle A = \alpha + \delta$
$\angle B = \alpha + \beta$
$\angle C = \beta + \gamma$
$\angle D = \gamma + \delta$

Sum of all four = $2(\alpha + \beta + \gamma + \delta) = 360°$.

$\alpha + \beta + \gamma + \delta = 180°$

So $\angle A + \angle C = (\alpha+\delta) + (\beta+\gamma) = 180°$. Similarly $\angle B + \angle D = 180°$. $\blacksquare$

4 isosceles triangles ⇒ opposite angles = 180°

Pairing base angles of 4 isosceles △s ⇒ opposite angles sum = 180°

Ch-5 I’m Up and Down, and Round and Round class 9th maths ganita manjari ncert solution

Chapter 5I’m Up and Down,and Round and Round

Think and Reflect — Symmetries of a Circle

Think and Reflect — How Many Circles?

Circumcircles & Three Points

Think, Draw and Infer

Triangles Formed by Chords

Perpendicular Bisectors of Chords

Equal Chords & Pythagoras

Distance of Chords from the Centre

Angles Subtended by Arcs

Mixed Exercises

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Chapter 5
I’m Up and Down,
and Round and Round