X2 t08 01 circle geometry (2013)

Harder Extension 1 Circle Geometry

Harder Extension 1

Converse Circle Theorems Circle Geometry

Harder Extension 1

Converse Circle Theorems Circle Geometry

(1) The circle whose diameter is the hypotenuse of a right angled

triangle passes through the third vertex.

Harder Extension 1

Converse Circle Theorems Circle Geometry

(1) The circle whose diameter is the hypotenuse of a right angled

triangle passes through the third vertex.

A B

C

Harder Extension 1

Converse Circle Theorems Circle Geometry

(1) The circle whose diameter is the hypotenuse of a right angled

triangle passes through the third vertex.

A B

C ABC are concyclic with AB diameter

Harder Extension 1

Converse Circle Theorems Circle Geometry

(1) The circle whose diameter is the hypotenuse of a right angled

triangle passes through the third vertex.

A B

C ABC are concyclic with AB diameter

90 semicircle ain

Harder Extension 1

Converse Circle Theorems Circle Geometry

(1) The circle whose diameter is the hypotenuse of a right angled

triangle passes through the third vertex.

A B

C ABC are concyclic with AB diameter

90 semicircle ain

(2) If an interval AB subtends the same angle at two points P and Q on

the same side of AB, then A,B,P,Q are concyclic.

Harder Extension 1

Converse Circle Theorems Circle Geometry

(1) The circle whose diameter is the hypotenuse of a right angled

triangle passes through the third vertex.

A B

C ABC are concyclic with AB diameter

90 semicircle ain

(2) If an interval AB subtends the same angle at two points P and Q on

the same side of AB, then A,B,P,Q are concyclic.

A B

P Q

Harder Extension 1

Converse Circle Theorems Circle Geometry

(1) The circle whose diameter is the hypotenuse of a right angled

triangle passes through the third vertex.

A B

C ABC are concyclic with AB diameter

90 semicircle ain

(2) If an interval AB subtends the same angle at two points P and Q on

the same side of AB, then A,B,P,Q are concyclic.

A B

P Q ABQP is a cyclic quadrilateral

Harder Extension 1

Converse Circle Theorems Circle Geometry

(1) The circle whose diameter is the hypotenuse of a right angled

triangle passes through the third vertex.

A B

C ABC are concyclic with AB diameter

90 semicircle ain

(2) If an interval AB subtends the same angle at two points P and Q on

the same side of AB, then A,B,P,Q are concyclic.

A B

P Q ABQP is a cyclic quadrilateral

aresegment samein s

(3) If a pair of opposite angles in a quadrilateral are supplementary (or

if an exterior angle equals the opposite interior angle) then the

quadrilateral is cyclic.

(3) If a pair of opposite angles in a quadrilateral are supplementary (or

if an exterior angle equals the opposite interior angle) then the

quadrilateral is cyclic.

The Four Centres Of A Triangle

(3) If a pair of opposite angles in a quadrilateral are supplementary (or

if an exterior angle equals the opposite interior angle) then the

quadrilateral is cyclic.

The Four Centres Of A Triangle

(1) The angle bisectors of the vertices are concurrent at the incentre

which is the centre of the incircle, tangent to all three sides.

(3) If a pair of opposite angles in a quadrilateral are supplementary (or

if an exterior angle equals the opposite interior angle) then the

quadrilateral is cyclic.

The Four Centres Of A Triangle

(1) The angle bisectors of the vertices are concurrent at the incentre

which is the centre of the incircle, tangent to all three sides.

(3) If a pair of opposite angles in a quadrilateral are supplementary (or

if an exterior angle equals the opposite interior angle) then the

quadrilateral is cyclic.

The Four Centres Of A Triangle

(1) The angle bisectors of the vertices are concurrent at the incentre

which is the centre of the incircle, tangent to all three sides.

incentre

(3) If a pair of opposite angles in a quadrilateral are supplementary (or

if an exterior angle equals the opposite interior angle) then the

quadrilateral is cyclic.

The Four Centres Of A Triangle

(1) The angle bisectors of the vertices are concurrent at the incentre

which is the centre of the incircle, tangent to all three sides.

incentre incircle

(2) The perpendicular bisectors of the sides are concurrent at the

circumcentre which is the centre of the circumcircle, passing

through all three vertices.

(2) The perpendicular bisectors of the sides are concurrent at the

circumcentre which is the centre of the circumcircle, passing

through all three vertices.

(2) The perpendicular bisectors of the sides are concurrent at the

circumcentre which is the centre of the circumcircle, passing

through all three vertices.

circumcentre

(2) The perpendicular bisectors of the sides are concurrent at the

circumcentre which is the centre of the circumcircle, passing

through all three vertices.

circumcentre

circumcircle

(2) The perpendicular bisectors of the sides are concurrent at the

circumcentre which is the centre of the circumcircle, passing

through all three vertices.

circumcentre

circumcircle

(3) The medians are concurrent at the centroid, and the centroid trisects

each median.

(2) The perpendicular bisectors of the sides are concurrent at the

circumcentre which is the centre of the circumcircle, passing

through all three vertices.

circumcentre

circumcircle

(3) The medians are concurrent at the centroid, and the centroid trisects

each median.

(2) The perpendicular bisectors of the sides are concurrent at the

circumcentre which is the centre of the circumcircle, passing

through all three vertices.

circumcentre

circumcircle

(3) The medians are concurrent at the centroid, and the centroid trisects

each median.

centroid

(4) The altitudes are concurrent at the orthocentre.

(4) The altitudes are concurrent at the orthocentre.

(4) The altitudes are concurrent at the orthocentre.

orthocentre

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

O

P

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

O

P PA segment samein

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

O

P PA segment samein

PA sinsin

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

O

P PA segment samein

PA sinsin

90PBC

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

O

P PA segment samein

PA sinsin

90PBC 90semicirclein

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

O

P PA segment samein

PA sinsin

90PBC 90semicirclein

PPC

BCsin

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

O

P PA segment samein

PA sinsin

90PBC 90semicirclein

PPC

BCsin

PCP

BC

sin

(4) The altitudes are concurrent at the orthocentre.

orthocentre

Interaction Between Geometry & Trigonometry

lecircumcirc ifdiameter sinsinsin

C

c

B

b

A

a

Proof: A

B

C

O

P PA segment samein

PA sinsin

90PBC 90semicirclein

PPC

BCsin

PCP

BC

sin A

BCPC

sin

e.g. (1990)

In the diagram, AB is a fixed chord of a circle, P a variable point in the

circle and AC and BD are perpendicular to BP and AP respectively.

e.g. (1990)

In the diagram, AB is a fixed chord of a circle, P a variable point in the

circle and AC and BD are perpendicular to BP and AP respectively.

(i) Show that ABCD is a cyclic quadrilateral on a circle with AB as

diameter.

e.g. (1990)

In the diagram, AB is a fixed chord of a circle, P a variable point in the

circle and AC and BD are perpendicular to BP and AP respectively.

(i) Show that ABCD is a cyclic quadrilateral on a circle with AB as

diameter.

90 ACBBDA

e.g. (1990)

In the diagram, AB is a fixed chord of a circle, P a variable point in the

circle and AC and BD are perpendicular to BP and AP respectively.

(i) Show that ABCD is a cyclic quadrilateral on a circle with AB as

diameter.

90 ACBBDA given

e.g. (1990)

In the diagram, AB is a fixed chord of a circle, P a variable point in the

circle and AC and BD are perpendicular to BP and AP respectively.

(i) Show that ABCD is a cyclic quadrilateral on a circle with AB as

diameter.

90 ACBBDA given

ralquadrilate cyclic a is ABCD

e.g. (1990)

In the diagram, AB is a fixed chord of a circle, P a variable point in the

circle and AC and BD are perpendicular to BP and AP respectively.

(i) Show that ABCD is a cyclic quadrilateral on a circle with AB as

diameter.

90 ACBBDA given

ralquadrilate cyclic a is ABCD aresegment samein s

e.g. (1990)

In the diagram, AB is a fixed chord of a circle, P a variable point in the

circle and AC and BD are perpendicular to BP and AP respectively.

(i) Show that ABCD is a cyclic quadrilateral on a circle with AB as

diameter.

90 ACBBDA given

ralquadrilate cyclic a is ABCD aresegment samein s

90 semicirclein asdiameter is AB

(ii) Show that triangles PCD and APB are similar

(ii) Show that triangles PCD and APB are similar

DPCAPB

(ii) Show that triangles PCD and APB are similar

DPCAPB scommon

(ii) Show that triangles PCD and APB are similar

DPCAPB scommon

PBAPDC

(ii) Show that triangles PCD and APB are similar

DPCAPB scommon

PBAPDC ralquadrilate cyclic exterior

(ii) Show that triangles PCD and APB are similar

DPCAPB scommon

PBAPDC ralquadrilate cyclic exterior

PBAPDC |||

(ii) Show that triangles PCD and APB are similar

DPCAPB scommon

PBAPDC ralquadrilate cyclic exterior

PBAPDC ||| requiangula

(iii) Show that as P varies, the segment CD has constant length.

(iii) Show that as P varies, the segment CD has constant length.

P

A B

P

C D

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD

P

A B

P

C D

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

P

A B

P

C D

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

PAP

PCPCA cos,In

P

A B

P

C D

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

PAP

PCPCA cos,In

PAB

CDcos

P

A B

P

C D

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

PAP

PCPCA cos,In

PAB

CDcos

PABCD cos

P

A B

P

C D

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

PAP

PCPCA cos,In

PAB

CDcos

PABCD cos

constant is Now, P

P

A B

P

C D

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

PAP

PCPCA cos,In

PAB

CDcos

PABCD cos

constant is Now, P

P

A B

P

C D

aresegment samein s

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

PAP

PCPCA cos,In

PAB

CDcos

PABCD cos

constant is Now, P

P

A B

P

C D

fixed is and AB

aresegment samein s

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

PAP

PCPCA cos,In

PAB

CDcos

PABCD cos

constant is Now, P

P

A B

P

C D

fixed is and AB

aresegment samein s

given

(iii) Show that as P varies, the segment CD has constant length.

AP

PC

AB

CD s |||in sides of ratio

PAP

PCPCA cos,In

PAB

CDcos

PABCD cos

constant is Now, P

P

A B

P

C D

fixed is and AB

aresegment samein s

givenconstant is CD

(iv) Find the locus of the midpoint of CD.

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD M

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD

O is the midpoint of AB

M

O

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD

O is the midpoint of AB

M

O

OM is constant

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD

O is the midpoint of AB

M

O

OM is constant

centre thefromt equidistan are chords

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD

O is the midpoint of AB

M

O

OM is constant

centre thefromt equidistan are chords

OM from distance fixed a is

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD

O is the midpoint of AB

M

O

OM is constant

centre thefromt equidistan are chords

OM from distance fixed a is 222 MCOCOM

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD

O is the midpoint of AB

M

O

OM is constant

centre thefromt equidistan are chords

OM from distance fixed a is 222 MCOCOM

PAB

PABAB

PABAB

22

222

22

sin4

1

cos4

1

4

1

cos2

1

2

1

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD

O is the midpoint of AB

M

O

OM is constant

centre thefromt equidistan are chords

OM from distance fixed a is 222 MCOCOM

PAB

PABAB

PABAB

22

222

22

sin4

1

cos4

1

4

1

cos2

1

2

1

PABOM sin2

1

(iv) Find the locus of the midpoint of CD.

ABCD is a cyclic quadrilateral with AB diameter.

A B

C D Let M be the midpoint of CD

O is the midpoint of AB

M

O

OM is constant

centre thefromt equidistan are chords

OM from distance fixed a is 222 MCOCOM

PAB

PABAB

PABAB

22

222

22

sin4

1

cos4

1

4

1

cos2

1

2

1

PABOM sin2

1

PAB

O

sin2

1radius and

centre circle, is locus

2008 Extension 2 Question 7b)

In the diagram, the points P, Q and R lie on a circle. The tangent at P

and the secant QR intersect at T. The bisector of meets QR at S

so that . The intervals RS, SQ and PT have lengths

a, b and c respectively.

PQR

QPS RPS

2008 Extension 2 Question 7b)

In the diagram, the points P, Q and R lie on a circle. The tangent at P

and the secant QR intersect at T. The bisector of meets QR at S

so that . The intervals RS, SQ and PT have lengths

a, b and c respectively.

PQR

QPS RPS

( ) Show that i TSP TPS

2008 Extension 2 Question 7b)

In the diagram, the points P, Q and R lie on a circle. The tangent at P

and the secant QR intersect at T. The bisector of meets QR at S

so that . The intervals RS, SQ and PT have lengths

a, b and c respectively.

PQR

QPS RPS

( ) Show that i TSP TPS

RQP RPT

2008 Extension 2 Question 7b)

In the diagram, the points P, Q and R lie on a circle. The tangent at P

and the secant QR intersect at T. The bisector of meets QR at S

so that . The intervals RS, SQ and PT have lengths

a, b and c respectively.

PQR

QPS RPS

( ) Show that i TSP TPS

RQP RPT alternate segment theorem

2008 Extension 2 Question 7b)

In the diagram, the points P, Q and R lie on a circle. The tangent at P

and the secant QR intersect at T. The bisector of meets QR at S

so that . The intervals RS, SQ and PT have lengths

a, b and c respectively.

PQR

QPS RPS

( ) Show that i TSP TPS

RQP RPT alternate segment theorem

TSP RQP SPQ

2008 Extension 2 Question 7b)

In the diagram, the points P, Q and R lie on a circle. The tangent at P

and the secant QR intersect at T. The bisector of meets QR at S

so that . The intervals RS, SQ and PT have lengths

a, b and c respectively.

PQR

QPS RPS

( ) Show that i TSP TPS

RQP RPT alternate segment theorem

TSP RQP SPQ exterior , SPQ

2008 Extension 2 Question 7b)

In the diagram, the points P, Q and R lie on a circle. The tangent at P

and the secant QR intersect at T. The bisector of meets QR at S

so that . The intervals RS, SQ and PT have lengths

a, b and c respectively.

PQR

QPS RPS

( ) Show that i TSP TPS

RQP RPT alternate segment theorem

TSP RQP SPQ exterior , SPQ

TSP RPT

SPT RPT

SPT RPT common

SPT RPT common

SPT TSP

SPT RPT common

SPT TSP

1 1 1( ) Hence show that ii

a b c

SPT RPT common

SPT TSP

1 1 1( ) Hence show that ii

a b c

SPT RPT common

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

SPT RPT

common

2 = 's

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS 2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c

2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c = sides in isosceles

2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c = sides in isosceles 2PT QT RT

2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c = sides in isosceles 2PT QT RT

square of tangents=products of intercepts

2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c = sides in isosceles 2PT QT RT

square of tangents=products of intercepts

2c c b c a

2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c = sides in isosceles 2PT QT RT

square of tangents=products of intercepts

2c c b c a

2 2c c ac bc ab

2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c = sides in isosceles 2PT QT RT

square of tangents=products of intercepts

2c c b c a

2 2c c ac bc ab

bc ac ab

2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c = sides in isosceles 2PT QT RT

square of tangents=products of intercepts

2c c b c a

2 2c c ac bc ab

bc ac ab

1 1 1

a b c

2 = 's

common SPT RPT

SPT RPT

SPT TSP

1 1 1( ) Hence show that ii

a b c

is isoscelesTPS

ST c = sides in isosceles 2PT QT RT

square of tangents=products of intercepts

2c c b c a

2 2c c ac bc ab

bc ac ab

1 1 1

a b c

Past HSC Papers

Exercise 10C*

2 = 's

common SPT RPT