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97 Vedanta Excel in Mathematics Teachers' Manual - 9 4. i. ii. iii. In 'DBC and 'ABC BD = AC (S) ‘DBC = ‘ACB (A) BC = BC (S) 4. i. ii. iii. From (3) Given Common side 5. 'DBC # 'ABC 5. By S.A.S. axiom 6. CD = AB 6. Corresponding sides of congruent triangle are equal Proved 44. In the figure alongside, PQRS is a square. U is the mid - point of PQ, ‘RUT = 90°, TU and RQ are produced to meet at V. Prove that : TR = PT  PQ Solution: Given: PQRS is a square, U is the mid - point of PQ and ‘RUT = 90° To prove: TR = PT  PQ Proof Statements Reasons 1. i. ii. iii. In 'PUT and 'UVQ ‘TPU = ‘UQV (A) PU = UQ (S) ‘PUT = ‘VUQ (A) 1. i. ii. iii. Both are right angles U is the mid - point of PQ Vertically opposite angles 2. 'PUT # 'UVQ 2. By A.S.A. axiom 3. PT = VQ and UT = UV 3. Corresponding sides of congruent triangle are equal 4. i. ii. iii. In 'TUR and 'UVR UT = UV (S) ‘TUR = ‘VUR (A) UR = UR (S) 4. i. ii. iii. From (3) Both are right angles Common sides 5. 'TUR # 'UVR 5. By S.A.S. axiom 6. TR = VR 6. Corresponding sides of congruent triangles 7. VR = VQ  QR = PT  PQ 7. Whole part axiom, VQ = PT and QR = PQ 8. TR = PT  PQ 8. From (6) and (7) Proved 45. In the adjoining figure, AC = BC, ‘PCA = ‘QCB and ‘PBA = ‘QAB. Prove that 'OPQ is an isosceles triangle. Solution: Given: AC = BC, ‘PCA = ‘QCB and ‘PBA = ‘QAB To prove: 'OPQ is an isosceles triangle Proof Statements Reasons 1. ‘PCA = ‘QCB 1. Given 2. ‘PCA  ‘PCQ = ‘QCB  ‘PCQ 2. Adding ‘PCQ on both sides of (1) 3. ‘ACQ  ‘PCB 3. From (2), by whole part axiom P T Q R V U S A B O P Q C

Vedanta Excel in Mathematics Teachers' Manual - 9 98 4. i. ii. iii. In 'QAC and 'PCB ‘QAC = ‘PBC (A) AC = BC (S) ‘ACQ = ‘PCB (A) 4. i. ii. iii. Given Given From (3) 5. 'QAC # 'PCB 5. By A.S.A. axiom 6. ‘AQC = ‘BPC 6. Corresponding angles of congruent triangle 7. CQ = CP 7. Corresponding sides of congruent triangle 8. ‘CQP = ‘CPQ 8. From (7) 9. CQP  ‘AQC = ‘CPQ  ‘BPQ i.e, ‘OQP = ‘OPQ 9. Subtracting (6) from (8) 10. 'OPQ is an isosceles tringle 10. Base angle are equal Proved Mid - point theorems 1. In 'PQR, X and Y are mid - points of PQ and PR respectively. If ‘P  ‘Q = 50° and ‘P  ‘R = 150°, find size of ‘PXY and ‘PYX. Solution: In 'PQR, X and Y are the mid - point of PQ and PR respectively. ? XY // QR. i) ‘R = 180°  (‘P  ‘Q) = 180 °  50° = 130° ? ‘PYX = ‘R = 130° [? XY // QR, corresponding angles] ii) ‘Q = 180°  (‘P  ‘R) = 180°  150° = 30° ? ‘PXY = ‘Q = 30° [ ? XY // PQ, corresponding angles] 2. In the given 'ABC, P, Q and R are the mid - point of sides AB, BC and CA respectively. If the perimeter of 'PQR is 15 cm. find the perimeter of 'ABC. Solution: i) PQ = 1 2 AC, QR = 1 2 AB and PR = 1 2 BC [line segment that joins the mid points of two sides is half of the third side in triangle.] ii) Perimeter of 'PQR = 15 cm or, PQ  QR  PR = 15 cm or, 1 2 (AC  AB  BC) = 15 cm ? AB  BC  AC = 30 cm Hence, the perimeter of 'ABC is 30 cm. 3. In the given figures, AD // BC and P is the mid - point of AB. If BC = 8cm and QR = 3cm, find the length of PQ and AD. Solution: i) In 'ABC, AQ = QC [? AP = PB and PQ // BC] PQ = 1 2 BC [PQ joints the mid - points of the sides AB and AC] = 1 2 u 8 cm = 4 cm P Q R X Y A B C P R Q A D R C Q P B

99 Vedanta Excel in Mathematics Teachers' Manual - 9 ii) In 'ACD; CR = RD [?AQ = QC and QR // AD] ? QR = 1 2 AD [? Q and R joint the mid - point of AC and CD] or, 3 cm = 1 2 AD ? AD = 6 cm 4. In the adjoining figures, P and Q are the mid - point of the sides AB and AC of 'ABC respectively. X is a point on PQ. Prove that AX = XD. Solution: Given: In 'ABC, P and Q are the mid - point of the sides AB and AC respectively. X is a point on PQ. To prove: AX = XD Proof Statements Reasons 1. In 'ABC, PQ // BC 1. PQ joins the mid - points of the sides AB and AC 2. In 'ABD; AX = XD 2. PX // BD and P is the mid point of AB Proved 5. In the adjoining triangle XYZ, A and B are the mid - point of the sides XY and YZ respectively. P is any point on XZ. Prove that AB bisects PY at Q. Solution: Given: In 'XYZ; A and B are the mid - points of sides XY and YZ respectively. P is any point on XY. To prove: AB bisects PY at Q Proof Statements Reasons 1. In 'XYZ, AB // XZ 1. AB joins the mid - points of XY and YZ 2. In 'PXY, YQ = QP 2. AP // XP, and A is the mid - point of side XY 3. AB bisects PY at Q 3. From (2) Proved 6. In the adjoining equilateral triangle PQR. X, Y and Z are the middle points of the sides PQ, QR and RP respectively. Prove that XYZ is also an equilateral triangle. Solution: Given: 'PQR is an equilateral triangle. X, Y and Z are the mid - points of the sides PQ, QR and RP respectively. To prove: 'XYZ is also an equilateral triangle Proof Statements Reasons 1. PQ = QR = RP 1. 'PQR is an equilateral triangle

Vedanta Excel in Mathematics Teachers' Manual - 9 100 2. YZ = 1 2 PQ, ZX = 1 2 QR and XY = 1 2 RP 2. ? Line joins the mid - points of any two sides of the triangle is half of the third side 3. YZ = ZX = XY 3. From (1) and (2) 4. 'XYZ is also the equilateral triangle 4. From (3) Proved 7. In the given figure, AB // DC. If E is the mid - point of BC and F is the mid - point of AC, prove that G is the mid - point of AD. Solution: Given: AB // DC, E is the mid - point of BC and F is the mid - point of AC. To prove: G is the mid - point of AD. Proof Statements Reasons 1. In 'ABC, FE // AB 1. EF join the mid - points of sides BC and AC 2. AB // DC 2. Given 3. AB // FE // DC i.e, AB // GE // DC 3. From (1) and (2) 4. In 'ADC, G is the mid - point of AD 4. GE // DC and F is the mid - point of AC Proved 8. In the adjoining figure, AB // CD // PQ and AP = PC. Prove that: AB  CD. Solution: Given: AB // CD // PQ and AP = PC To prove: AB = CD Proof Statements Reasons 1. Q is mid - point of BC 1. ? In 'ABC, AP = PC and PQ // AB 2. PQ = 1 2 AB 2. PQ joins the mid - point of AC and BC in 'ABC 3. Q is mid - point of AD 3. ? In 'ADC, AP = PC and PQ // CD 4. PQ = 1 2 CD 4. PQ joins the mid - point of AC and AD in 'ABC 5. AB = CD 5. From (ii) and (iv) Proved 9. In the figure alongside, AD // PQ // BC and DQ = QC. Prove that AD  BC = 2PQ. Solution: Given: AD // PQ // BC and DQ = QC To prove: AD  BC = 2PQ Proof Statements Reasons 1. In 'ADC, AR = RC 1. DQ = QC and RQ // AD

101 Vedanta Excel in Mathematics Teachers' Manual - 9 2. RQ = 1 2 AD ?AD = 2RQ 2. RQ joins the mid - points of side AC and DC 3. In 'ABC, AP = PB 3. AR = RC and PR // BC 4. PR = 1 2 BC ? BC = 2PR 4. ? PR joins the mid - point of sides AB and AC 5. AD  BC = 2RQ  2PR 5. Adding (ii) and (iv) vi. AD  BC = 2PQ 6. Whole part axiom, PR  RQ = PQ Proved 10. In the figure alongside, P is the mid - point of BC. PQ // CA and QR // BC. Prove that BC = 4QR. Solution: Given: P is mid - point of BC, PQ // CA and QR // BC To prove: BC = 4QR Proof Statements Reasons 1. In 'ABC, AQ = BQ 1. PQ // CA and BP = PC 2. In 'ABD, AR = RP 2. QR // BC and AQ = BQ, from (1) 3. QR = 1 2 BP 3. From (1) and (2) 4. BP = 1 2 BC 4. P is the mid - point of BC 5. QR = 1 2 u 1 2 BC ? BC = 4QR 5. From (3) and (4) Proved 11. In the given 'ABC, AX and BY are medians, Z is a point on BC such that YZ // AX. Prove that BC = 4CZ Solution: Given: In 'ABC, AX and BY are median. Z is a point on BC and YZ // AX. To prove: BC = 4CZ Proof Statements Reasons 1. X is mid - point of BC and Y is the mid - point of AC 1. Being AX and BY the median of 'ABC 2. Z is mid - point of CX i.e, CZ = ZX i.e, CZ = 1 2 CX ? CX = 2CZ 2. In 'ACX, AY = YC and YZ // AX 3. CX = 1 2 BC 3. BX = CX 4. 2CZ = 1 2 BC ?BC = 4CZ 4. From (2) and (3) Proved P R B A Q C X Z C A Y B

Vedanta Excel in Mathematics Teachers' Manual - 9 102 12. In the given figure, A is the mid - point of QR and B is the mid - point of PA. Prove that PC = 1 3 PQ. Solution: Given: A is the mid - point of QR and B is the mid - point of PA To prove: PC = 1 3 PQ Construction: AD // BC is drawn where D is on PQ. Proof: Statements Reasons 1. In 'PAD; PC = CD 1. PB = AB and BC // AD 2. In 'QCR, CD = QD 2. QA = AR and AD // CR 3. PC = CD = QD 3. From (1) and (2) 4. PC = 1 2 PQ 4. From (3) Proved 13. In the given right angled triangle ABC, right angled at B, P is the mid - point of AC. Prove that BP = 1 2 AC. Solution: Given: ABC is a right angled triangle, right angled at B, P is the mid - point of AC. To prove: BP = 1 2 AC. Proof: Statements Reasons 1. BQ = QC 1. In 'ABC, PQ // AB and AP = CP 2. ‘PQC = ‘ABC = 90° 2. PQ // AB, corresponding angles 3. i. ii. iii. In 'PQC and 'PQB CQ = BQ (S) ‘PQC = ‘PQB (A) PQ = PQ (S) 3. i. ii. iii. From (1) Both are right angles, From (2) Common side 4. 'PQC # 'PQB 4. By S.A.S axiom 5. PC = BP 5. Corresponding sides of congruent triangles 6. PC = 1 2 AC 6. ?AP = PC 7. BP= 1 2 AC 7. From (5) and 6 Proved P R B A Q C P R B A Q C

103 Vedanta Excel in Mathematics Teachers' Manual - 9 14. In the given 'ABC, AP is the bisector of ‘BAC. If BO A AP and OQ // AC, prove that BQ = QC Solution: Given: In 'ABC, AP is the bisector of ‘BAC. BO A AP and OQ // AC. To prove: BQ = QC. Construction: BO is produced to meet AC at D. Proof: Statements Reasons 1. i. ii. iii. In 'AOB and 'AOD ‘BAO = ‘OAD (A) AO = AO (S) ‘AOB = ‘AOD 1. i. ii. iii. Given Common side Both are right angles 2. 'AOB # 'AOD 2. By A.S.A. axiom 3. BO = OD 3. Corresponding side of congruent triangle are equal 4. BQ = QC 4. In 'BCD, BO = OD and OQ // DC. Proved 15. In the given trapezium PQRS, A and B are the mid - point of the diagonals QS and PR respectively. Prove that (i) AB // SR (ii) AB = 1 2 (SR  PQ) Solution: Given: In trapezium PQRS, A and B are the mid - point of the diagonals QS and PR respectively. To prove: (i) AB // SR (ii) AB = 1 2 (SR  PQ) Construction: QB is produced to meet SR at C. Proof: Statements Reasons 1. i. ii. iii. In 'PQB and 'CBR ‘QPB = ‘BRC (A) PB = BR (S) ‘PBQ = ‘CBK (A) 1. i. ii. iii. PQ // CR and alternate angles B is the mid - point of PR Vertically opposite angles are equal 2. 'PQB # 'CBR 2. By A.S.A. axiom 3. BQ = BC and PQ = CR 3. Corresponding sides of congruent triangles are equal 4. AB // SC i.e, AB // SR and AB = 1 2 SC 4. In 'QSC, AB joins the mid - point of sides QS and QC 5. SC = SR  CR 5. Subtraction axiom 6. AB = 1 2 (SR - PQ) 6. From (3), (4) and (5) Proved A B P Q O C A B P Q O C D

Vedanta Excel in Mathematics Teachers' Manual - 9 104 16. In the adjoining trapezium PQRS, X and Y are the mid - point of PS and QR respectively. Prove that: XY = 1 2 (PQ  SR) Solution: Given: X and Y are the mid - point of PS and QR respectively in trapezium PQRS. To prove: XY = 1 2 (PQ  SR) Construction: QX is joined and produced to meet RS produced at T. Proof: Statements Reasons 1. i ii. iii. In 'PXQ and 'TXS ‘XPQ = ‘TSX (A) PX = SX (S) ‘PXQ = ‘TXS (A) 1. i. ii. iii. PQ // TR and alternate angles Given Vertically opposite angles are equal 2. 'PXQ # 'TXS 2. By A.S.A. axiom 3. PQ = TS and QX = TX 3. Corresponding sides of congruent triangle 4. XY // TR and XY = 1 2 TR 4. XY join the mid - points of sides QT and QR respectively in 'QTR 5. TR = TS  SR 5. Whole part axiom 6. XY = 1 2 (PQ  SR) 6. From (3), (4) and (5) Proved 17. In the adjoining figure, PQRS and MQNO are rectangles. Prove that: (1) MQ = 1 2 SR (ii) MN = 1 2 QS. Solution: Given: PQRS and MQNO are rectangles To prove: (i) MQ = 1 2 SR (ii) MN = 1 2 QS Proof: Statements Reasons 1. ON // SR 1. ? ‘ONQ = ‘SRQ = 90°, corresponding angles 2. O is mid - point of QS 2. Diagonals of rectangle bisect each other 3. N is mid - point of QR 3. From (1) and (2) 4. ON = 1 2 SR 4. From (2) and (3) 5. MQ = 1 2 SR 5. ON = MQ 6. M is the mid - point of PQ 6. MO // PS and QO = OS 7. MN // PR and MN = 1 2 PR 7. From (3) and (6) 8. MN = 1 2 QS 8. ? PR = QS, diagonals of rectangles Proved S R P Q S R P Q T X P Q M N R O S

105 Vedanta Excel in Mathematics Teachers' Manual - 9 18. In the figure alongside, M is the mid - point of BC, Q is the mid - point of MR and AB // NM // CQ. Prove that: (i) PR = 3PM (ii) AB = 4CQ Solution: Given: M is the mid - point of BC, Q is the mid - point of MR and AB // NM // CQ. To prove: (i) PR = 3PM (ii) AB = 4CQ Proof: Statements Reasons 1. AN = NC 1. In 'ABC, AB // NM and BM = MC 2. MN = 1 2 AB 2. MN joins the mid - point of BC and AC respectively 3. NC = CR 3. In 'NMR, NM // CQ and MQ = QR 4. CQ = 1 2 NM 4. CQ joins the mid - point NR and MR respectively 5. CQ = 1 2 u 1 2 AB ? AB = 4CQ 5. From (2) and (4) 6. i. ii. iii. In 'PBM and 'CQM ‘PBM = ‘MCQ (A) BM = MC (S) ‘BMP = ‘CMQ (A) 6. i. ii. iii. PB // CQ and alternate angles Given Vertically opposite angles 7. 'PBM # 'CQM 7. By A.S.A. axiom 8. PM = MQ 8. Corresponding sides of congruent triangle are equal 9. PM = MQ = QR 9. Given and statement (8) 10 PR = 3PM 10. From (9) Proved A B C M N Q R P

Vedanta Excel in Mathematics Teachers' Manual - 9 106 Unit 12 Geometry - Similarity Allocated teaching periods 3 Competency - To identify the geometric figures of similar shapes and solve the related problems Learning Outcomes - To indicate the condition of similarity on polygons (triangles and polygons) and solve the problems related problems Level-wise learning objectives S.N. LEVELS OBJECTIVES 1. Knowledge (K) - To define similarity on polygons - To tell the conditions of similarity of triangles - To recall the Pythagoras theorem 2. Understanding (U) - To find the sides of similar triangles or polygons - To show the similarity of given triangles 3. Application (A) - To prove the theorems based on similarity of triangles 4. High Ability (HA) - To prove the Pythagoras theorem by the virtue of the similarity of triangles - To explore the required relations based similar triangles Required Teaching Materials/ Resources Various photos of same shapes, card boards of different sizes but same shapes, leafs of shame tree, models of enlargement and reduction etc Pre-knowledge: Congruent triangles, similar triangles Teaching Activities 1. For warm-up, show the pair of square/circular sheet of paper, Nepali flags, leafs, photos etc and discuss upon the properties so observed 2. Divide the students into 4 groups and do the following activities - Provide a pair of similar triangles to group-A - Provide a pair of similar quadrilaterals to group-B - Provide a pair of similar pentagons to group-C - Provide a pair of similar hexagons to group-D Then tell them to discuss in own group, measure the corresponding sides and angles, their relations and present the own result in the class. 3. Also, ask the following questions (i) Are the corresponding sides of similar triangles equal? (ii) Are the corresponding sides of similar triangles proportional? (iii) Are the corresponding angles of similar triangles equal? (iv) Are the corresponding angles of similar polygons equal? (v) Are the corresponding sides and perimeter of similar polygons equal? (vi) Are the corresponding sides and diagonals of similar polygons equal?

107 Vedanta Excel in Mathematics Teachers' Manual - 9 Solution of selected problems from Vedanta Excel in Mathematics 1. In the given figure, 'ABC a 'ABD, ‘BAD = ‘ACB, find the length of BD. Solution: Here, 'ABC a ABD ? AB BD = AB BD [Corresponding sides of similar triangle are proportional] or, 4 cm BD = 8 cm 4 cm ? BD = 2 cm Hence, the length of BD is 2 cm. 2. In the adjoining figure, AB // QC, PR = 2RQ and QC = 3 cm. Find the length of AP with the suitable reasons. Solution: Statements Reasons 1. i. ii. iii. In 'APR and 'QCR ‘APR = ‘RQC ‘PAR = ‘RCQ ‘ARP = QRC 1. i. ii. iii. AB // QC and alternate angles Same as (i) Vertically opposite angles are equal 2. 'APR a 'QCR 2. By A.A.A. axiom 3. AP QC = PR QR or, AP 3 cm = 2 RQ RQ ? AP = cm 3. Corresponding sides of similar triangle are proportional 3. In a given right angled triangle ABC right angled at B, BD A AC and ‘CBD = ‘BAC. Prove that: (i) 'ABC a 'BCD (ii) 'BCD a 'ABD (iii) BC2 = AC.CD (iv) BD2 = AD.CD (v) BC2 BC2 = AC AD Solution: Given: 'ABC is a right angled triangle in which ‘ABC = 90q, BD A AC and ‘CBD = ‘BAC To prove: (i) 'ABC a 'BCD (ii) 'BCD a 'ABD (iii) B C2 = AC.CD (iv) BD2 = AD.CD (v) BC2 BC2 = AC AD A 4 cm B D8 cm C A 4 cm B 8 cm C A 4 cm B D A C B P R Q 3 cm 4. Discuss on the conditions of similarity of triangles 5. Solve the problems from the exercise with discussion. 6. Focus on project work

Vedanta Excel in Mathematics Teachers' Manual - 9 108 Proof Statements Reasons 1. i. ii. In 'ABC and 'BCD ‘ABC = ‘BCD ‘ACB = ‘BCD 1. i. ii. Both are right angles Common angles 2. 'ABC a 'BCD 2. By A.A fact 3. AB BD = BC CD = AC BC ? BC2 = AC.CD 3. Corresponding sides of similar triangle are proportion From 2nd and 3rd ration 4. i. ii. In 'BCD and 'ABD ‘BDC = ‘ADB ‘DBC = ‘BAD 4. i. ii. Both are right angles Given 5. 'BCD a 'ABD 5. By A.A. fact 6. BC AB = BD AD = CD BD ? BD2 = AD.CD 6. Corresponding sides of similar triangle are proportion From 2nd and 3rd ration 7 BC2 BD2 = AC.CD AD.CD = AC AD 7. From (3) and (6) Proved 4. In the given figure, 'ADE = ‘ACB and ‘DAC = ‘BAE. Prove that, AD.BC = AC.DE. Solution: Given: ‘ADE = ‘ACB and ‘DAC = ‘BAE. To prove: AD.BE = AC.DE Proof Statements Reasons 1. ‘DAC = ‘BAE 1. Given 2. ‘DAE = ‘BAC 2. Adding ‘EAC on both sides of (1) 3. i. ii. In 'ADE and 'ABC ‘ADE = ‘ACB ‘DAE = ‘BAC 3. i. ii. Given From (2) 4. 'ADE a 'ABC 4. By A.A axiom 5. AE AB = DE BC = AD AC 5. Being corresponding sides of similar triangles 6. AD.BC = AC.DE 6. From (5), taking last two ration Proved 5. In the given figure, AB = DC, AB // DC and M is the mid - point of AB. Prove that: (i) 'AOM a 'COD (ii) CO = 2AO Solution: Given: AB = DC, AB // DC and M is the mid - point of AB. To prove: (i) 'AOM a 'COD (ii) CO = 2AO A B C D E

109 Vedanta Excel in Mathematics Teachers' Manual - 9 Proof Statements Reasons 1. i. ii. In 'AOM and 'COD ‘OAM = ‘OCD ‘AOM = ‘COD 1. i. ii. AB // DC and alternate angles Vertically opposite angles 2. 'AOM a 'COD 2. By A.A. axiom 3. AO CO = OM OD = AM CD 3. Corresponding sides of similar triangle 4. AB = 2AM and AB = CD 4. Given 5. AO CO = AM 2AM ? CO = 2AO Proved 6. In the given figure, AB // MN // DC. If AB = x, DC = y and MN = z. Prove that 1 x  1 y = 1 z . Solution: Given: AB // MN // DC, AB = x, DC = y and MN = z. To prove: 1 x  1 y = 1 z Proof Statements Reasons 1. i. ii. iii. In 'ABC and 'MNC ‘ABC = ‘MNC ‘BAC = ‘NMC ‘ACB = ‘MCN 1. i. ii. iii. AB // MN, corresponding angles Same as (i) Common angles 2. 'ABC a 'MNC 2. By A.A.A. axiom 3. AB MN = BC NC or, x z = BC NC ? NC = z x BC Corresponding sides of similar triangles 4. i. ii. iii. In 'BCD and 'BNM ‘BCD = ‘BNM ‘BDC = ‘BMN ‘DBC = ‘MBN 4. i. ii. iii. MN // DC, corresponding angles Same as 4(i) Common angles 5. 'BCD a BNM 5. By A.A.A. axiom 6. DC MN = BC BN or, y z = BC BN ? BN = z y BC 6. Corresponding sides of similar triangles 7. NC  BN = zBC 1 x  1 y 7. Adding (3) and (6) 8. BC = zBC 1 x  1 y ? 1 x  1 y = 1 z 8. NC  BN = BC Proved A B x N C M D y z

Vedanta Excel in Mathematics Teachers' Manual - 9 110 Extra Questions 1. In the given figure, 'ABC aMNC, find the value of x. [Ans: 1.6 cm] 2. In the adjoining figure, XZ = 15 cm, PZ = 10 cm QZ = 6 cm and XY // PQ. Find the length of YQ [Ans: 3 cm] 3. In the figure given alongside 'ABC a 'ADC. Find the value of x. [Ans: 6] 4. In the given figure, ‘BAC = 90q, AD A BC, CD = 9 cm and BC = 12 cm, find the length of AB. [Ans: 6 cm] B. Pythagorean Theorem 1. In the adjoining right angled triangle ABC, D is any point on AB. Prove that AB2  AD2 = BC2 CD2 Solution: Statements Reasons 1. AB2  AC2 = BC2 ? AC2 = BC2  AB2 1. Using Pythagoras theorem in 'ABC 2. AD2  AC2 = CD2 ? AC2 = CD2  AD2 2. Using Pythagoras theorem in 'ADC 3. BC2  AB2 = CD2  AD2 ? BC2  CD2 = AB2  AD2 3. From (1) and (2) Proved 2. In the given right angled triangle ABC, M is the mid - point of BC. Prove that AC2 = AM2  3CM2 Solution: Statements Reasons 1. AB2  BM2 = AM2 1. By Pythagoras theorem x C N M B A 2 cm 3 cm 4 cm X Y Q P Z 2 cm 10 cm 15 cm A B C D E (x  4)cm x cm (x  3)cm (x  2)cm A 4 cm B D 9 cm C 12 cm

111 Vedanta Excel in Mathematics Teachers' Manual - 9 2. AB2  CM2 = AM2 ? AB2 = AM2  CM2 2. BM = CM and from (1) 3. AB 2  BC2 = AC2 3. By Pythagoras theorem 4. AB2  (2cm)2 = AC2 4. From (3), BC = 2 cm 5. AM2  CM2  4 cm2 = AC2 ? AC2 = AM2  3 cm2 5. From (2) and (4) Proved 3. In the given figure, X is the mid - point of PQ. Prove that PQ2 =(RX2  PR2 ) Solution: Statements Reasons 1. PQ = 2PX ? PQ2 = (2PX)2 = 4PX2 1. X being the mid - point of PQ 2. PX2 = RX2  PR2 2. In 'PRX, by Pythagoras theorem 3. PQ2 = 4(RX2  PR2 ) 3. From (1) and (2) Proved 4. ABC is an isosceles triangle in which AB = AC = 2BC. If AD is an altitude of the triangle. Prove that 4 AD2 = 15 BC2 . Solution: Statements Reasons 1. BD = CD = 1 2 BC 1. Altitude of isosceles triangle bisects its base 2. AD2  BD2 = AB2 or, AD2  (1 2 BC)2 = (2BC)2 or, 4AD2  BC2 = 16BC2 ? 4AD2 = 15BC2 2. In 'ABD, by Pythagoras theorem BD = 1 2 BC and AB = 2BC Proved 5. In the given figure, diagonals of a quadrilateral PQRS are intersected at T at right angle. Prove that: PQ2  SR2 = QR2  PS2 Solution: Given: The diagonals of the quadrilateral PQRS intersect at T at a right angle. To prove: PQ2  SR2 = QR2  PS2 R P Q X A B C D P Q R S T

Vedanta Excel in Mathematics Teachers' Manual - 9 112 Proof Statements Reasons 1. In 'PQT, QT2 = PQ2  PT2 In 'QTR, QT2 = QR2  TR2 Thus, PQ2  PT2 = QR2  TR2 ? PQ2 = QR2  PT2  TR2 1. By using Pythagoras therorm 2. In 'PST, ST2 = PS2  PT2 In 'STR, ST2 = SR2  TR2 Thus, PS2  PT2 = SR2  TR2 ? SR2 = PS2  PT2  TR2 2. Same as (1) 3. PQ2  SR2 = QR2  PT2  TR2  PS2  PT2  TR2 ? PQ2  SR2 = QR2  PS2 3. From (1) and (2) Proved 6. In the figure alongside, O is any point interior to the rectangle. Prove that OX2  OY2 = OW2  OZ2 . Solution: Given: O is any point interior to the rectangle WXYZ. To prove: OX2  OY2 = OW2  OZ2 Construction: PQ // XY is drawn through O where P is on WX and Q is on YZ Proof Statements Reasons 1. OP A XW and OQ A YZ 1. PQ // XY and ‘X = ‘Y = 90q 2. OP2 = OW2  PW2 and OP2 = OX2  PX2 or, OW2  PW2 = OX2  PX2 ? OX2 = OW2  PX2  PW2 2. In 'POW and 'POX using Pythagoras therorm 3. OQ2 = OZ2  QZ2 and OQ2 = OY2  QY2 or, OZ2  QZ2 = OY2  QY2 ? OY2 = OZ2  QZ2  QY2 3. In 'QOZ and 'QOY using Pythagoras therorm 4. OX2  OY2 = OW2  PX2  PW2  (OZ2  QZ2  QY2 ) = OW2  OZ2  PX2  PW2  QZ2  QY2 4. Subtracting (3) from (2) 5. OX2  OY2 = OW2  OZ2  QY2  PW2  PW2  QY2 ? OX2  OY2 = OW2  OZ2 5. PX = QY, QZ = PW Proved W X Y Z O W X Y Z O P Q

113 Vedanta Excel in Mathematics Teachers' Manual - 9 Allocated teaching periods 10 Competency - To prove the theorems and properties of parallelograms and verify the other properties by inductive method. Learning Outcomes - To prove the theorems and properties of parallelograms - To verify the other properties of parallelogram by experimental or inductive method. Level-wise learning objectives S.N. LEVELS OBJECTIVES 1. Knowledge (K) - To define parallelogram - To recall the types of parallelogram - To tell the properties of parallelogram - To recall the relations between corresponding parts of parallelogram (rectangle, square and rhombus). 2. Understanding (U) - To calculate the size of unknown angles based on properties of parallelograms 3. Application (A) - To prove the theorems on properties of parallelogram - To verify the properties of the parallelogram by inductive method 4. High Ability (HA) - To prove more theorems by drawing realted diagrams/ figure Required Teaching Materials/ Resources Colourful chart-paper, scale, scissors, pencil, geo-board, rubber bands, tangram, marker, models of measuring tape, ICT tools etc Pre-knowledge: Congruency of triangles, types of parallelograms, mid-point theorem etc. Teaching Activities 1. Present the parallelograms on the geo-board by using rubber bands or make parallelograms using a rectangular piece of paper along with students and recall about parallelograms. 2. With the figure on the chart-paper, prove the theorems with students. 3. Rename the same theorem and give to students to prove them. 4. Select the students randomly and call to prove the theorem on the board. Unit 13 Parallelogram

Vedanta Excel in Mathematics Teachers' Manual - 9 114 Solution of selected problems from Vedanta Excel in Mathematics 1. In the given figure, PQRS is a rhombus and SRM is an equilateral triangle. If SN A RM and ‘PRS = 55°, find the size of ‘QSN. Solution: (i) In rhombus PQRS, ³SOR = 900 [Diagonals of rhombus bisect each other perpendicularly] ? ³OSR = 1800 – (900 + 550 ) = 450 (ii) In equilateral 'SRN; ³SRN= 600 [Each angle of equilateral triangle] ? ³RSN = 1800 – (900 + 600 ) = 300 Hence, ³QSN = ³OSR +³RSN = 450 + 300 = 750 2. In the adjoining figure, PQRS is a rectangle. If OP = (2x – 3) cm and OR = (x + 1) cm, find the length of diagonal QS. Solution: (i) OP = OR [Diagonals of rectangle bisect each other] or, 2x – 3 = x + 1 ?x = 4 and PR = OP + OR = (2x – 3)+(x+1) = 10 cm (ii) PR= QS [Diagonals of rectangle are equal] ?QS = 10 cm 3. RACE is a rectangle in which diagonal RC = 18 cm, OA = (p + q) cm and OE = 3p cm, find the values of p and q. Solution: (i) AE = RC = 18 cm [Diagonals of rectangle are equal] (ii) OA= OE = 9 cm [Diagonals of rectangle bisect each other] Now, OE = 9 cm or, 3p = 9 cm ?p = 3 cm Again, OA = 9 cm or, p + q = 9 cm or, 3 cm + q = 9 cm ?q = 6 cm 4. In the adjoining figure ABCD is a square and ABE is an equilateral triangle. Find the measure of ‘ADE and ‘DCE. Solution: (i) ³DAB = 900 [Being an angle of the square] (ii) ³EAB = 600 [Being an angle of the equilateral triangle] ? ³DAE = 900 – 600 = 300 (iii) ³ADE = ³AED [ AD = AE] Now, ³ADE + ³AED + ³DAE=1800 or, 2³ADE +300 = 1800 ?³ADE = 750 (iv) ³BCE = 750 [Same as the above process] ?³DCE= 900 – 750 = 150 5. In the given figure, ABCD is a parallelogram. AP bisects ‘A. Prove that DP = BC. Solution: Given: In the parallelogram ABCD; AP bisects ³A. S R (x+1)cm (2x–3)cm Q O P R E 3p cm (p+q)cm C O A D A B E C 55° P S R N M Q O

115 Vedanta Excel in Mathematics Teachers' Manual - 9 To prove: DP = BC Proof:  ³DAP = ³BAP [AP bisects ³A]  ³APD = ³BAP [DC//AB, alternate angles]  ³DAP = ³APD [From (1) and (2)] (4) DP = AD [From (3), the base angles of 'ADP are equal] (5) AD = BC [Opposite sides of parallelogram are equal] (6) DP = BC [From (4) and (5)] 6. In the given figure, EXAM is a parallelogram, the bisector of ‘A meets the mid-point of EM at P. Prove that AX = 2AM. Solution: Given: In the parallelogram EXAM; the bisector of ³A meets the midpoint of EM at P. To prove: AX = 2AM Proof: (1) ³XAP = ³MAP [AP is the bisector of ³A] (2) ³XAP = MPA [EM//XA, alternate angles] (3) ³MAP = MPA [From (1) and (2)] (4) PM = AM [From (3), the base angles of 'ADP are equal] (5) ME = 2PM [P is the mid-point of ME] (6) ME = AX [Opposite sides of parallelogram are equal] (7) AX = 2AM [From (4),(5) and (6)] 7. In the adjoining figure, ABCD is a rhombus in which CD is produced to E such that CD = DE. Prove that ‘EAC = 90°. Solution: Given: In the rhombus ABCD; CD is produced to E such that CD = DE. To prove: ³EAC = 900 Proof: (1) AD = CD [Adjacent sides of the rhombus are equal] (2) CD = DE [Given] (3) AD = CD = DE [From (1) and (2)] (4) ³AEC = ³EAD [From (3), AD = DE] (5) ³DAC = ³ACE [From (3), AD = CD] (6) ³AEC + ³EAC +³ACE = 1800 [Sum of angles of triangle] (7) ³EAD + ³EAC +³DAE = 1800 [From (4), (5) and (6)] (8) ³EAC + ³EAC = 1800 [From (7), ³EAD + ³DAE = ³EAC] (9) ³EAC = 900 [From (8)] E X A M P E D C B A

Vedanta Excel in Mathematics Teachers' Manual - 9 116 8. In the given figure, P and R are the mid–points of the sides AB and BC of ∆ABC respectively. If PQ // BC, prove that BP = RQ. Solution: Given: In 'ABC; P and R are the mid-points of the sides AB and BC respectively PQ // BC. To prove: BP = RQ Proof: (1) AQ = QC [In 'ABC;PQ//BC and AP = BP] (2) QR //AB [AQ = QC and BR = RC] (3) PQRB is a parallelogram [From (2) and PQ // BC] (4) BP = RQ [Opposite sides of the //gm PQRB] 9. In the given quadrilateral PQRS, the mid–points of the sides PQ, QR, RS and SP are A, B, C and D respectively. Prove that ABCD is a parallelogram. Solution: Given: In quadrilateral PQRS; the mid-points of sides PQ, QR, RS and SP are A, B, C and respectively. To prove: ABCD is a parallelogram Construction: Diagonal PR of the quadrilateral PQRS is drawn Proof: (1) In 'PQR, AB//PR and AB = 1 2 PR [AB joins the mid points of PQ and QR] (2) In 'PSR, DC//PR and AB = 1 2 PR [CD joins the mid points of RS and SP] (3) AB//DC and AB = DC [From (1) and (2)] (4) BC//AD and BC =AD [From (3)] (5) ABCD is a parallelogram [From (3) and (4)] 10. In the adjoining figure, P, Q, R and S are the mid-points of AB, BC, CD and AD respectively. Prove that PQRS is a parallelogram. Solution: Given: P, Q, R and S are the mid-points of sides AB, BC, CD and AD respectively To prove: PQRS is a parallelogram Construction: AC is joined. Proof: (1) In 'ABC, PQ//AC and PQ = 1 2 AC [PQ joins the mid points of AB and BC] (2) In 'ADC, SR//AC and SR = 1 2 AC [SR joins the mid points of AD and CD] (3) PQ//SR and PQ = SR [From (1) and (2)] (4) QR//PS and QR = PS [From (3)] (5) PQRS is a parallelogram [From (3) and (4)]

117 Vedanta Excel in Mathematics Teachers' Manual - 9 11. In the given figure, P, Q, R and S are the mid-points of AB, BC, CD and AD respectively. Prove that PQRS is a parallelogram. Solution: Given: P, Q, R and S are the mid-points of sides AB, BC, CD and AD respectively To prove: PQRS is a parallelogram Construction: BD is joined. Proof: (1) In 'ABD, PS//BD and PS = 1 2 BD [PS joins the mid points of AB and AD] (2) In 'BCD, QR//AC and PS = 1 2 BC [QR joins the mid points of BC and CD] (3) PS//QR and PS = QR [From (1) and (2)] (4) PQ//SR and PQ = SR [From (3)] (5) PQRS is a parallelogram [From (3) and (4)] 12. In the given figure, PQRS is a square. A, B, C and D are the points on the sides PQ, QR, RS and SP respectively. If AQ = BR = CS = DP, prove that ABCD is also a square. Solution: Given: PQRS is a square. AQ = BR = CS = DP To prove: ABCD is the square. Proof: (1) AQ = BR = CS = DP [Given] (2) PA = BQ = CR = SD [Remaining parts of equal sides] (3) In 'AQB and 'BRC (i) AQ = BR (ii) ³AQB = ³BRC (iii) BQ = CR [From (1)] [Both are right angles] [From (2)] (4) 'AQB # 'BRC [By S.A.S axiom] (5) AB = BC and ³ABQ = ³BCR [Corresponding parts of congruent triangles] (6) ³CBR + ³BCR = 900 [Sum of acute angles in rt. ³ed 'BCR] (7) ³CBR + ³ABQ = 900 [From (5) and (6) (8) ³CBR + ³ABQ + ³ABC = 1800 [Being the parts of a straight angle] ?³ABC = 900 (9) 'BCR # 'CDS, 'CDS # 'AQB [By S.A.S axiom] (10) BC = CD and CD = AD [Corresponding sides of congruent triangles] (11) ABCD is a square [ From (5), (9) and (10)] A B D C P Q R S

Vedanta Excel in Mathematics Teachers' Manual - 9 118 13. In the given parallelogram PQRS, PA bisects ‘P and RB bisects ‘R. Prove that PA // BR. Solution: Given: In the parallelogram PQRS, PA bisects ³A and RB bisects ³R To prove: PA//BR Proof: (1) ³SPQ = 2³APQ and ³QRS = 2³BRS [Given] (2) ³SPQ = ³QRS [Opposite angles of parallelogram] (3) ³APQ = ³BRS [From (1) and (2)] (4) ³APQ = ³SAP [SR//PQ, alternate angles] (5) ³BRS = ³SAP [From (3) and (4)] (6) PA//BR [Corresponding angles are equal] 14. ABCD is a parallelogram. P and Q are two points on the diagonal BD such that DP = QB. Prove that APCQ is a parallelogram. Solution: Given: In the parallelogram ABCD, P and Q are two points on the diagonals BD such that DP = QB To prove: APCQ is a parallelogram Proof: (1) OA = OC and OD = OB [Diagonals of parallelogram bisect each other] (2) DP = QB [Given] (3) OA = OB and OP = OQ [OD-DP = OP, OB – QB =OQ ] (4) APCQ is a parallelogram [From (3), diagonals are bisected each other] 15. ABCD is a parallelogram. DE A AC and BF A AC. Prove that BEDF is a parallelogram. Solution: Given: ABCD is a parallelogram. DEAAC and BFAAC To prove: BEDF is a parallelogram Proof: (1) In 'DAE and 'BCF (i) ³AED = ³BFC [Both are right angles] (ii) ³DAE= ³BCF [DA//BC, alternate angles] (iii) AD = BC [Opposite sides of parallelogram] (2) 'DAE # 'BCF [By A.A.S. axiom] (3) AP = QC [Corresponding sides of congruent triangles] (4) DE//FB [³AED = ³BFC, alternate exterior angles are equal] (5) DF = EB, DF//EB [From (3) and (4)] (6) BEDF is a parallelogram [From (3), (4) and (5)]

119 Vedanta Excel in Mathematics Teachers' Manual - 9 16. In parallelogram PQRS, the bisectors of ‘PQR and ‘PSR meet the diagonal at M and N respectively. Prove that MQNS is a parallelogram. Solution: Given: In //gm PQRS, the bisectors of ³PQR and ³PSR meet the diagonal PR at M and N respectively i.e., ³PQM = ³RSN and ³PSN = ³RSN To prove: MQNS is a parallelogram Proof: (1) In 'PQM and 'RSN (i) ³PQM = ³RSN [Given and ³PQR= ³PSR] (ii) PQ = RS [Opposite sides of parallelogram] (iii) ³QPM= ³SRN [PQ//SR, alternate angles] (2) 'PQM # 'RSN [By A.S.A. axiom] (3) MQ = SN, ³PMQ = ³SNR [Corresponding parts of congruent triangles] (4) MQ//SN [From(3), alternate exterior angles are equal] (5) MS=QN, MS//QN [From (3) and (4)] (6) MQNS is a parallelogram [From (3), (4) and (5)] 17. In the given figure, ABCD is a parallelogram. If P and Q are the points of trisection of diagonal BD, prove that PAQC is a parallelogram. Solution: Given: In parallelogram ABCD, P and Q are the points of trisections of the diagonal BD. i.e., BP = PQ = QD To prove: PAQC is a parallelogram Proof: (1) In 'ABP and 'CDQ (i) AB = CD [Opposite sides of parallelogram] (ii) ³ABP = ³CDQ [AB//CD, alternate angles] (ii) BP =QD [Given] (2) 'ABP # 'CDQ [By S.A.S. axiom] (3) AP = CQ, ³APB = ³CQD [Corresponding parts of congruent triangles] (4) AP//QC [From(3), alternate exterior angles are equal] (5) AQ = PC, AQ//PC [From (3) and (4)] (6) PAQC is a parallelogram [From (3), (4) and (5)] 18. In the figure, ABCD is a parallelogram. M and N are the mid-points of the sides AB and DC respectively. Prove that (i) MBCN is a parallelogram (ii) DMBN is a parallelogram (iii) DB and MN bisect each other at O. P Q R S M N A B C D P Q

Vedanta Excel in Mathematics Teachers' Manual - 9 120 Solution: Given: In parallelogram ABCD, M and N are the mid-points of the sides AB and DC respectively To prove: (i) MBCN is a parallelogram (ii) DMBN is a parallelogram (iii) DB and MN bisect each other Proof: (1) AB = DC and AB // DC [Opposite sides of parallelogram] (2) MB = CN and MB//CN [M and N are the mid-points of AB and DC] (3) MN = BC and MN//BC [From (2)] (4) MBCN is a parallelogram [From (2) and (3)] (5) DM = BN and DM//BN [MB=DN and MB//DN] (6) DMBN is a parallelogram [From (5)] (7) DB and MN bisect each other [Being the diagonals of parallelogram DMBN] 19. In the given parallelogram PQRS, M and N are the midpoints of the sides PQ and SR respectively. Prove that (i) PNRM is a parallelogram (ii) QA = AB = BS Solution: Given: In parallelogram ABCD, M and N are the mid-points of the sides PQ and SR respectively To prove: (i) PNRM is a parallelogram (ii) QA = AB = BS Proof: (1) PM = NR and PM // NR [PQ = SR, PQ//SR and given] (2) PN = MR and PM//MR [From (1)] (3) PNRM is a parallelogram [From (1) and (2)] (4) QA = AB [In 'PQB, PM = QM and MA // PB] (5) AM = BS [In 'SAR, SN = RN and BN// AR] (6) QA = AB = BS [From (4) and (5)] 20. ABCD is a square. P and Q are any points on the sides AB and BC respectively. If AQ = DP, prove that AQ and DP are perpendicular to each other. Solution: Given: In square ABCD, P and Q are the points on the sides AB and BC respectively To prove: AQ and DP are perpendicular to each other. AQ = DP Proof: (1) In 'DAP and 'ABQ (i) ³DAP = ³ABQ (R) [Both are right angles] (ii) DP = AQ (H) [Given] (iii) DA = AB (S) [Adjacent sides of the square ABCD] (2) 'DAP #'ABQ [By R.H.S. axiom] (3) ³ADP = ³BAQ [Corresponding angles of congruent triangles] (4) ³DAQ + ³ADP = 900 [From (3) and ³DAP = ³DAQ + ³QAP = 900 ] (5) ³AOD = 900 [From (4), remaining angle of 'AOD] Hence, AQ and DP are perpendicular each other.

121 Vedanta Excel in Mathematics Teachers' Manual - 9 21. In the figure along side, ABCD and DEFC are parallelograms. Prove that (i) AE = BF (ii) 'ADE # 'BCF Solution: Given: ABCD and DEFC are parallelograms. To prove: (i) AE = BF (ii) 'ADE # 'BCF Proof: (1) AB = DC, AB//DC [Opposite sides of parallelogram ABCD] (2) DC = EF, DC//EF [Opposite sides of parallelogram DEFC] (3) AB = EF and AB//EF [From (1) and (2)] (4) AE = BF and AE//BF [From (3)] (6) In 'ADE and 'BCF (i) AE = BF (S) [From (4)] (ii) AD = BC (S) [Opposite sides of parallelogram ABCD] (iii) DE= CF (S) [Opposite sides of parallelogram DEFC] (7) 'ADE #'BCF [By S.S.S. axiom] 22. In the given quadrilateral ABCD, AD = BC, P and Q are the mid-points of the diagonals AC and BD respectively. If M and N are the mid-points of the sides DC and AB respectively, prove that PMQN is a parallelogram. Solution: Given: In quadrilateral ABCD, AD = BC, P and Q are the mid-points of the diagonals AC and BD respectively, M and N are the mid-points of the sides DC and AB respectively. To prove: PMQN is a rhombus Proof: NP//DA and NP = 1 2 DA [Applying mid-point theorem in 'CDA] QM//DA and QM = 1 2 DA [Applying mid-point theorem in 'BDA] (1) NP//QM and NP = QM [From (1) and (2)] (2) PM//NQ and PM = NQ [From (3)] (3) NP = PM = QM = NQ [AD = BC] (4) PMQN is a rhombus [From (5)] 23. In the adjoining figure, ABCD is a parallelogram. AS, BS, CQ and DQ are the bisectors of ‘A, ‘B, ‘C and ‘D respectively. Prove that PQRS is a rectangle. Solution: Given: In parallelogram ABCD; AS, BS, CQ and DQ are the bisectors of ³A, ³B, ³C and ³D respectively. To prove: PQRS is a rectangle D C A B P Q M N D C P S R Q A B

Vedanta Excel in Mathematics Teachers' Manual - 9 122 Proof: (1) ³DAB = 2³DAS = 2³BAS, ³ABC = 2³ABS = 2³CBS, ³BCD = 2³BCQ = 2³DCQ and ³ADC = 2³ADQ = 2³CDQ [Given] (2) ³DAB +³ABC = 1800 [AD//BC, co-interior angles] (3) 2³BAS + 2³ABS = 1800 [From (1) and (2)] ?BAS + ³ABS = 900 (4) ³BAS + ³ABS + ³ASB = 1800 [Sum of angles of triangle ABS] (5) ³ASB = 900 [From (3) and (4)] (6) ³CQD = ³SPQ = ³SRQ = 900 [Same as above process] (7) PQRS is a rectangle [From (5) and (6)] 24. Prove that the diagonals of a rectangle are equal. Solution: Given: ABCD is a rectangle in which AC and BD are the diagonals To prove: AC = BD Proof: (1) In 'ABC and 'BCD (i) AB = CD (S) [Opposite sides of rectangle are equal] (ii) ³ABC = ³BCD (A) [Both are right angles] (iii) BC = BC (S) [Common side] (2) 'ABC # 'BCD [By S.A.S. axiom] (3) AC = BD [Corresponding sides of congruent triangles] 25. If the diagonals of a rhombus are equal, prove that it is a square. Solution: Given: In rhombus ABCD, AC = BD To prove: ABCD is a square Proof: (1) In 'ABC and 'BCD (i) AB = CD (S) [Opposite sides of rectangle are equal] (ii) BC = BC (S) [Common side] (iii) AC = BD (S) [Given] (2) 'ABC # 'BCD [By S.S.S. axiom] (3) ³ABC = ³BCD [Corresponding angles of congruent triangles] (4) ³ABC + ³BCD = 1800 [AB//DC and co-interior angles] (5) ³ABC = 900 [From (3) and (4)] (6) ABCD is a square [From (5) and AB = BC = CD = A] 26. Prove that the diagonals of a rhombus bisect each other perpendicularly. Solution: Given: In rhombus ABCD, the diagonals AC and BD intersect at O. D A B C

123 Vedanta Excel in Mathematics Teachers' Manual - 9 To prove: Diagonals AC and BD bisect each other perpendicularly i.e., OA = OC, OB = OD and ³AOB = 900 Proof: (1) In 'AOB and 'AOD (i) AB = AD (S) [Sides of rhombus are equal] (ii) ³BAO = ³DAO (A) [Diagonal AC bisects ³A] (iii) OA = OA (S) [Common side] (2) 'AOB # 'AOD [By S.A.S. axiom] (3) OB = OD [Corresponding sides of congruent triangles] (4) ³AOB =³AOD [Corresponding angles of congruent triangles] (5) ³AOB = ³AOD = 900 [Being linear pair] (6) 'AOB # 'BOC [Same as above process] (7) OA = OC [Corresponding sides of congruent triangles] (8) AC and BD bisect each other perpendicularly at O [From (3), (5) and (7)] 27. In the adjoining quadrilateral PQRS, ‘P = ‘R and ‘Q = ‘S. Show that PQRS is a parallelogram. Solution: Given: In quadrilateral PQRS, ³P = ³R and ³Q = ³S To prove: PQRS is a parallelogram Proof: (1) ³P = ³R and ³Q = ³S [Given] (2) ³P+³R+³Q+³S=3600 [Sum of angles of quadrilateral] (3) ³R+³R+³S+³S=3600 [From (i) and (ii)] ?³R +³S=1800 (4) PS//QR [From (3) co-interior angles are supplementary] (5) PQ//SR [Same as above process] (6) PQRS is a parallelogram [From (4) and (5)] 28. In the given quadrilateral ABCD, AO = OC and BO = OD. Prove that ABCD is a parallelogram. Solution: Given: In quadrilateral PQRS, OA = OC and OB = OD To prove: ABCD is a parallelogram Proof: (1) In 'AOD and 'BOC (i) OA= OC (S) [Given] (ii) ³AOD = ³BOC (A) [Vertically opposite angles are equal] (iii) OD = OB (S) [Given] (2) 'AOD # 'BOC [By S.A.S. axiom] (3) AD = BC and ADO = ³OBC [Corresponding parts of congruent triangles] (4) AD//BC [From (3), alternate angles are equal] (5) AB//DC and AB=DC [From (3) and (4)] (6) ABCD is a parallelogram [From (3),(4) and (5)] S P Q R D C A B O

Vedanta Excel in Mathematics Teachers' Manual - 9 124 29. In the adjoining parallelogram ABCD, P and Q are the mid-points of the sides AD and BC respectively. Prove that BP and QD trisect the diagonal AC at X and Y respectively. Solution: Given: In parallelogram ABCD, P and Q are the mid-points of the sides AD and BC respectively To prove: BP and QD trisect AC at X and Y i.e., AX = XY = YC Proof: (1) PD = BQ and PD // BQ [AD = BC, AD//BC and given] (2) PB = DQ and B//DQ [From (1)] (3) AX = XY [In 'ADY, AP = PD and PX // DY] (4) XY = YC [In 'BCX, BQ = QC and YQ// XB] (5) AX = XY = YC [From (3) and (4)] 30. In the given parallelogram PQRS, M and N are the midpoints of the sides SR and QR respectively. If the diagonal PR and QS intersect at H, prove that MRNH is a parallelogram. Solution: Given: In parallelogram PQRS, M and N are the mid-points of the sides SR and QR respectively To prove: MRNH is a parallelogram Proof: (1) HP = HR and HQ = HS [Diagonals of parallelogram bisect each other] (2) PS//QR and PQ//SR [Opposite sides of parallelogram PQRS] (3) In 'QSR, HN// SR [HN joins mid-points of the sides QS and QR] (4) In 'PSR, HM// PS [HM joins mid-points of the sides PR and SR] (5) HN//SR and HM//QR [From (2), (3) and (4)] (6) MRNH is a parallelogram [From (5)] 31. In the figure alongside, ABCD is a quadrilateral in which OA = OC, OB = OD and ‘ AOB = ‘ AOD = ‘ DOC = ‘ COB = 90°. Prove that ABCD is a rhombus. Solution: Given: In quadrilateral ABCD, OA = OC, OB = OD and ³AOB = ³AOD = ³DOC = ³COB = 900 To prove: ABCD is a rhombus Proof: (1) In 'AOB and 'BOC (i) OA= OC (S) [Given] (ii) ³AOB = ³BOC (A) [Both are right angles] (iii) OB = OB (S) [Common side] (2) 'AOB # 'BOC [By S.A.S. axiom] (3) AB = BC [Corresponding sides of congruent triangles] (4) 'BOC # 'COD and 'COD # 'AOB [Same as above process] (5) BC = CD = AD [Corresponding sides of congruent triangles] (6) ABCD is a rhombus [From (3) and (5)] P S R M N H Q A B D C O

125 Vedanta Excel in Mathematics Teachers' Manual - 9 32. In the adjoining figure, EFGH is a parallelogram and P is the mid-point of FG. EP and HG are produced to meet at Q. Prove that AQ = 2HG. Solution: Given: In parallelogram EFGH, P is the mid-point of FG. EP and HG produced meet at Q. To prove: HQ = 2HG Proof: (1) In 'EFP and 'GPQ (i) ³PEF = ³PQG (A) [HQ//EF, alternate angles] (ii) ³EPF = ³GPQ (A) [Vertically opposite angles are equal] (iii) FP = GP (S) [Given] (2) 'EFP # 'GPQ [By A.A.S. axiom] (3) EF= GQ [Corresponding sides of congruent triangles] (4) EF = HG [Opposite sides of parallelogram EFGH] (5) HQ = 2HG [From (3) and (4)] 33. In the adjoining figure, ABCD is a rectangle and P, Q, R and S are the mid-points of AB, BC, CD and DA respectively. Prove that PQRS is a rhombus. Solution: Given: In rectangle ABCD; P, Q, R and S are the mid-points of AB, BC, CD and DA respectively To prove: PQRS is a rhombus Proof: Proof: (1) SA = SD = BQ = QC [S and Q are mid-points of AD and BC] (2) DR = CR = AP = BP [R and P are mid-points of DC and AB] (3) In 'SDR and 'RCQ (i) SD = QC (S) [From (1)] LL ³SDR = ³RCQ (A) [Both are right angles] (iii) DR = CR (S) [From (2)] (4) 'SDR # 'RCQ [By S.A.S. axiom] (5) SR = QR [Corresponding sides of congruent triangles] (6) 'RCQ # 'PQB # 'ASP [Same as above process] (7) QR = PQ = PS [Corresponding sides of congruent triangles] (8) PQRS is a rhombus [From (5) and (7)] 34. In the given square ABCD, E, F, G and H are the mid-points of AB, BC, CD and DA respectively. Prove that EFGH is also a square. Solution: Given: In square ABCD; E, F, G and H are the mid-points of AB, BC, CD and DA respectively To prove: EFGH is a square Proof: (1) In 'HAE and 'EBF (i) HA = BF (S) [H and F are mid-points of AD and BC, AD =BC] (ii) ³HAE = ³EBF (A) [Both are right angles] H G E F Q P A P B D C Q R S A B E D C F G H

Vedanta Excel in Mathematics Teachers' Manual - 9 126 (iii) AE = BE (S) [E is the mid-point of AB (2) 'HAE # 'EBF [By S.A.S. axiom] (3) HE = EF and ³AEH = ³BEF [Corresponding parts of congruent triangles] (4) 'EBF# 'FCG # 'HDG [Same as above process] (5) EF = FG = HG [Corresponding sides of congruent triangles] (6) ³AEH = ³BEF = 450 [Acute angles of isosceles right angled triangles] (7) ³AEH +³BEF+ ³HEF= 1800 [Being parts of straight angle] (8) ³HEF= 900 [From (6) and (7)] (9) PQRS is a square [From (3), (5) and (8)] 35. In the given figure, ABCD is a parallelogram. If P and Q are the mid-points of the sides AB and DC respectively, prove that RC = 2 AQ. Solution: Given: In parallelogram ABCD; P and Q are the mid-points of AB and DC respectively To prove: RC = 2AQ Proof: (1) QC = AP and QC//AP [DC = AB, DC//AB and given] (2) AQ = PC and AQ//PC [From (1)] (3) DA = AR [DQ = QC and AQ//PC] In 'DRC, AQ = 2 1 RC [AQ joins the mid-points of DR and DC] ?RC = 2 AQ 36. In the given figure, P, Q, R and S are the mid-points of AB, BC, CD and AD respectively. Prove that PQRS is a parallelogram. Solution: Given: AB = AC, PB = CM and PQ//AM To prove: PM and QC bisect each other. i.e., OP = OM and OQ = OC Proof: (1) ³ABC = ³ACB [AB = AC] (2) ³PQB = ³ACB [PQ//AC, corresponding angles] (3) ³ABC= ³PQB [From (1) and (2)] (4) PB = PQ [From (3)] (5) PB = CM [Given] (6) PQ = CM [From (4) and (5)] (7) In 'POQ and 'COM (i) ³POQ = ³COM (A) [Vertically opposite angles are equal] (ii) ³OPQ = ³OMC (A) [PQ//CM, alternate angles] (iii) PQ = CM (S) [From (6)] (8) 'POQ # 'COM [By A.A.S. axiom] (9) OP = OM and OQ = OC [Corresponding sides of congruent triangles] Hence, PM and QC bisect each other at O. D Q C A P B R Q O C M A B P

127 Vedanta Excel in Mathematics Teachers' Manual - 9 Unit 14 Circle Allocated teaching periods 10 Competency - To prove the properties of circle theoretically and experimentally and solve the related problems Learning Outcomes - To introduce the circle, prove the theorems on circle theoretically and verify them by induction method. Level-wise learning objectives S.N. LEVELS OBJECTIVES 1. Knowledge (K) - To define circle - To identify the parts of the circle - To tell the relation between the line segment joining the centre of the circle and the mid-point of the chord. - To write the relationship between the chords which are equidistance form the centre of the circle 2. Understanding (U) - To find the length of the radius / diameter of the circle - To calculate the length of the chord 3. Application (A) - To verify the properties of the circle - To prove the theorems on the circle - To find the distance between the parallel lines - To show the various relations of parts of circle based on the properties and theorems 4. High Ability (HA) - To represent the properties of triangles, quadrilaterals and circle diagrammatically and logically. - To establish the required relations using the properties of triangles, quadrilaterals and circle in the logical way. Required Teaching Materials/ Resources Geometric instruments, geo-board, rubber bands, card-boards, scissors, pencils, marker, ICT tool etc. Pre-knowledge: Circle adn its parts Teaching Activities 1. Give/ask real life examples of circular objects 2. Display circle and its parts in chart paper or card board or geo-board or ICT tools like geo-gebra and discuss 3. Experimentally verify and then prove (if possible) the following relations under discussion

Vedanta Excel in Mathematics Teachers' Manual - 9 128 (i) The radius of the circle are equal (ii) The perpendicular drawn from the centre of a circle to a chord bisects the chord. (iii) The line perpendicular to the chord passes through the centre of the circle (iv) The line segment joining the mid-point of a chord and the centre of circle is perpendicular to the chord. (v) The line Equal chords are equidistance from the centre. (vi) The chords which are equidistance form the centre of a circle are equal Solution of selected problems from Vedanta Excel in Mathematics 1. In the adjoining figure, O is the centre of both circle. If PX = 3 cm and AQ = 8 cm, find the length of XY. Solution: Here, O is the centre of circle, PX = 3 cm and AQ = 8 cm Now, (i) AP = AQ = 8 cm [QOAAPQ] (ii) AX = AP – PX = 8 cm – 3 cm = 5 cm (iii) XY = 2 AX = 2× 5 cm = 10 cm [QOAAXY] 2. In the figure alongside, O is the centre of a circle. AB = 20 cm, CD = 16 cm and AB // CD. Find the distance between AB and CD. Solution: Here, O is the centre of circle, AB = 20 cm, CD = 16 cm and AB//CD Construction: OP A CD is drawn and OC is joined Then, OC = radius = 10 cm Now, CP = 1 2 CD = 8 cm [QOPACD] In right angled triangle COP; OP = OC2 – CP2 = 102 – 82 = 6 cm Thus, the distance between the AB and CD is 6 cm 3. In the given figure, O is the centre of a circle. AB and CD are two parallel chords of lengths 16 cm and 12 cm respectively. If the radius of the circle is 10 cm, find the distance between the chords. Solution: Here, O is the centre of circle, AB = 16 cm, CD = 12 cm, radius = 10 cm and AB//CD Construction: OMA AB and ONA CD are drawn and, A and C are joined to O. Now, AM = 1 2 AB = 8 cm [QOM A AB] In right angled triangle AOM; OM = OA2 – AM2 = 52 – 42 = 3 cm Again, CN = 1 2 CD = 6 cm [QONACD] In right angled triangle CON; ON = OC2 – CN2 = 52 – 32 = 4 cm Now, MN = OM + ON = 6 cm + 8 cm = 14 cm Thus, the distance between the AB and CD is 14 cm. 4. In the adjoining figure, O is the centre of a circle, PQ and RS are two equal and parallel chords. If the radius of the circle is 5 cm and the distance between the chords is 8 cm, find the length of the chords. O P Q X A Y A B C D O A B C D O P A B O C D Q B O P R A B C D O M N

129 Vedanta Excel in Mathematics Teachers' Manual - 9 Solution: Here, O is the centre of circle, PQ = RS and PQ//RS Construction: OMA PQ and ONA RS are drawn and, P and O joined. Now, OM = 1 2 MN = 4 cm [Equal chords are equidistance from the centre] Again, in right angled triangle POM; OP2 – OM2 = 52 – 42 = 3 cm ?PQ = 2PM = 2× 3 cm = 6 cm Hence, the length of each of chords PQ and RS is 6 cm. 5. In a circle of radius 5 cm, AB and CD are two parallel chords of length 8 cm and 6 cm respectively. Calculate the distance between the chords, if they are (i) on the same side of the centre (ii) on the opposite side of the centre. Solution: Here, O is the centre of circle, radius = 5 cm, AB = 8 cm, CD = 6 cm and AB//CD (i) If AB and CD lie on the same side of the centre Construction: OMA AB and ONA CD are drawn and, A and C are joined to O. Now, AM = 1 2 AB = 4 cm [QOMAAB] In right angled triangle AOM; OM = OA2 – AM2 = 52 – 42 = 3 cm Again, CN = CD = 3 cm [QONACD] In right angled triangle CON; ON = OC2 – CN2 = 52 – 32 = 4 cm Now, MN = ON – OM = 4 cm – 3 cm = 1 cm Thus, the distance between the AB and CD is 1 cm. (ii) If AB and CD lie on the opposite side of the centre Construction: OMA AB is drawn and MO is produced to meet CD at N. So, ONA CD [QAB//CD] Now, AM = 1 2 AB = 4 cm [QOMAAB] In right angled triangle AOM; OM = OA2 – AM2 = 52 – 42 = 3 cm Again, CN = 1 2 CD = 3 cm [ONACD] In right angled triangle CON; ON = OC2 – CN2 = 52 – 32 = 4 cm Now, MN = OM + ON = 3 cm + 4 cm = 7 cm Thus, the distance between the AB and CD is 7 cm. 6. AB and CD are two parallel chords of a circle such that AB = 10 cm and CD = 24 cm. If the chords are on the opposite sides of the centre and the distance between them is 17 cm, find the radius of the circle. Solution: Here, O is the centre of circle, AB = 10 cm, CD = 24 cm and AB//CD AB and CD lie on the opposite side of the centre Construction: OMA AB is drawn and MO is produced to meet CD at N. So, C D O A B M N C D O A M B N C D O A M B N Q S O P R M N

Vedanta Excel in Mathematics Teachers' Manual - 9 130 ONA CD [QAB//CD] Let the radius of the circle OA = OC = r and OM = x then ON = MN – OM = (17 – x) cm Now, AM = 1 2 AB = 5 cm [QOMAAB] CN = 1 2 CD = 12 cm [QONACD] In right angled triangle AOM; OA2 = OM2 + AM2 = x2 + 52 = x2 + 25 In right angled triangle CON; OC2 = ON2 + CN2 = (17 – x)2 + 122 = 433 – 34x + x2 As OA = OC, OA2 = OC2 or, x2 + 25 = 433 – 34x + x2 ? x = 12 Again, OA2 = r2 = x2 + 25 = 122 + 25 = 169 ?r = 13 Hence, the radius of the circle is 13 cm. 7. In the given figure, O is the centre of the circle, chords MN and RS are intersecting at P. If OP is the bisector of ‘MPR, prove that MN = RS. Solution: Given: O is the centre of the circle, chords MN and RS intersect at P and OP is the bisector of ³MPR To prove: MN = RS Construction: OAA MN and OBA RS are drawn. Proof: (1) In 'AOP and 'BOP L ³OAP = ³OBP (A) [Both are right angles] LL ³OPA = ³OPB (A) [OP is the bisector of ³MPR] (iii) OP = OP (S) [Common side] (2) 'AOP # 'BOP [By A.A.S axiom] (3) OA = OB [Corresponding sides of congruent triangles] (4) MN = RS [From (3), chords equidistance from centre] 8. In the figure alongside, PQ and RS are two chords intersecting at T in a circle with centre O. If OT is the bisector of ‘PTR, prove that (i) PT = RT (ii) ST = TQ Solution: Given: O is the centre of the circle, chords PQ and RS intersect at T and OT is the bisector of ³PTR To prove: (i) PT = RT (ii) ST = TQ Construction: OAA PQ and OBA RS are drawn. Proof: (1) In 'AOT and 'BOT (i) ³OAT = ³OBT (A) [Both are right angles] (ii) ³OTA = ³OTB (A) [OP is the bisector of ³MPR] (iii) OT = OT (S) [Common side] (2) 'AOT # 'BOT [By A.A.S axiom] (3) OA = OB and AT = BT [Corresponding sides of congruent triangles] O M N R P S M A O B N R P S O P R Q T S O P R Q T S A B

131 Vedanta Excel in Mathematics Teachers' Manual - 9 (4) PQ = RS [From (3), chords equidistance from centre] (5) AP = BR [From (4) and OAAPQ, OBARS] (6) PT = RT [Adding (3) and (5), AT + AP = BT + BR] (7) ST = TQ [Subtracting (6) from (4), RS – RT = PQ – PT] 9. In the given figure, O is the centre of the circle. Two equal chords AB and CD intersect each other at E. Prove that (i) AE = CE (ii) BE = DE Solution: Given: O is the centre of the circle, equal chords AB and CD intersect at E To prove: (i) AE = CE (ii) BE = DE Construction: OMA AB and ONA CD are drawn, O and E are joined Proof: (1) In 'MOE and 'NOE (i) ³OME = ³ONE (R) [Both are right angles] (ii) OE = OE (H) [Common side] (iii) OM = ON (S) [Equal chords are equidistance form the centre] (2) 'MOE # 'NOE [By R.H.S axiom] (3) ME = NE [Corresponding sides of congruent triangles] (4) AM = CN [AB = CD and OMAAB, ONACD] (5) AE = CE [Adding (3) and (4), ME + AM = NE + CN] (6) AB = CD [Given] (7) BE = DE [Subtracting (5) from (6), AB – AE = CD – CE] 10. In the figure, L and M are the mid-points of two equal chords AB and CD of a circle with centre O. Prove that (i) ‘OLM = ‘OML (ii) ‘ALM = ‘CML Solution: Given: O is the centre of the circle, L and M are the mid-points of equal chords AB and CD respectively To prove: (i) ³OLM = ³OML (ii) ³ALM = ³CML Proof: (1) OL A AB, OM A CD [AL = BL and AM = DM] (2) ³OLA = ³OMC [From (1), both are right angles] (3) OL = OM [Equal chords are equidistance from the centre] (4) ³OLM = ³OML [From (3)] (5) ³ALM = ³CML [Subtracting (4) from (2)] 11. In the adjoining figure, AB is the diameter of a circle with centre O. If chord CD // AB, prove that ‘AOC = ‘BOD. Solution: Given: O is the centre of the circle, AB is the diameter and chord CD//AB O D C B E A O L C Q B D A M O A B C D O D C B M N E A

Vedanta Excel in Mathematics Teachers' Manual - 9 132 To prove: ³AOC = ³BOD Proof: (1) ³OCD= ³ODC [OC = OD] (2) ³OCD = ³AOC [AB//CD and alternate angles] (3) ³ODC = ³BOD [AB//CD and alternate angles] (4) ³AOC = ³BOD [From (1), (2) and (3)] 12. In the given figure, equal chords PQ and RS of a circle with centre O intersect each other at right angle at A. If M and N are the midpoints of PQ and RS respectively, prove that OMAN is a square. Solution: Given: O is the centre of the circle, equal chords PQ and RS intersect at right angle at A. M and N are the midpoints of PQ and RS To prove: OMAN is a square Proof: (1) OMAPQ [OM joins the centre O and mid-point M of the chord PQ] (2) ONARS [ON joins the centre O and mid-point N of the chord RS] (3) ³MAN = 900 [Given] (4) ³MAN = 900 [Remaining angle of the quadrilateral OMAN] (5) OM = ON [Equal chords of a circle are equidistance from the centre] (6) OMAN is a square [From (1), (2), (3), (4) and (5)] 13. In the adjoining figure, two chords WX and WY are equally inclined to the diameter at their point of intersection. Prove that the chords are equal. Solution: Given: O is the centre of the circle, chords WX and WY are equally inclined to the diameter WZ at W. To prove: Chords WX and WY are equal Construction: OMA WX and ONA WY are drawn Proof: (1) In 'MOW and 'NOW (i) ³ OMW = ³NOW (A) [Both are right angles] (ii) ³ OWM = ³OWN (A) [Given] (iii) OW = OW (S) [Common side]  'MOW # 'NOW [By A.A.S axiom] (3) OM = ON [Corresponding sides of congruent triangles] (4) WX = WY [From (3) and OMAXY, ONAYZ] 14. In the figure alongside, AB is a diameter. Two chords AD and BC are equal. Prove that AD // BC. Solution: Given: O is the centre of the circle, AB is the diameter, and chords AD and BC are equal S P Q A N M R O W Z X Y O W Z X Y O A B D C O

133 Vedanta Excel in Mathematics Teachers' Manual - 9 To prove: AD//BC Construction: OMA AD and ONA BC are drawn Proof: (1) In 'MOA and 'NOB (i) ³ OMA = ³ONB (R) [Both are right angles] (ii) OA = OB (H) [Radii] (iii) OM = ON (S) [Equal chords are equidistance from the centre] (2) 'MOA # 'NOB [By R.H.S axiom] (3) ³ OAM = ³OBN [Corresponding angles of congruent triangles] (4) AD//BC [From (3), alternate angles are equal] 15. In the given figure, AB and BC are equal chords of the circle with centre O. If OM A AB, ON A BC,OM and ON are produced to meet the circumference at P and Q respectively. Prove that: (i) AP = CQ (ii) ‘PAM = ‘QCN. Solution: Given: O is the centre of the circle, chords AB and BC are equal, OMAAB, ONABC, OM and ON are produced to meet the circumference at P and Q respectively. To prove: (i) AP = CQ (ii) ³PAM = ³QCN Proof: (1) OP = OQ [Radii] (2) OM = ON [Equal chords are equidistance from the centre] (3) PM = QN [Subtracting (2) from (1)] (4) In 'AMP and 'CNQ (i) PM = QN (S) [From (3)] (ii) ³ AMP = ³CNQ (A) [Given] (iii) AM = CN (S) [AB = BC, OMAAB and ONABC] (5) 'AMP # 'CNQ [By S.A.S axiom] (6) AP = CQ and ³PAM = ³QCN [Corresponding parts of congruent triangles] 16. Two equal chords AB and CD of a circle with centre O are produced to meet at E, as shown in the given figure. Prove that BE = DE and AE = CE. Solution: Given: O is the centre of the circle, equal chords AB and CD are produced to meet at E To prove: (i) BE = DE (ii) AE = CE Construction: OMAAB and ONACD are drawn Proof: (1) In 'MOE and 'NOE (i) ³ OME = ³ONE (R) [Both are right angles] (ii) OE = OE (H) [Common side] (iii) OM= ON (S) [Equal chords are equidistance from the centre] B N Q M A P C O D A B E C O B M N A D C O D A M B N E C O

Vedanta Excel in Mathematics Teachers' Manual - 9 134 (2) 'MOE # 'NOE [By R.H.S axiom] (3) ME = NE [Corresponding sides of congruent triangles] (4) MB =ND [AB=CD, OMAAB and ONACD] (5) BE = DE [Subtracting (4) from (3), ME – MB = NE – ND] (6) AM = CN [AB=CD, OMAAB and ONACD] (7) AE = CE [Adding (3) and (6), ME+AM = NE+CN] 17. In the given figure, O is the centre of circle ABCD. If OY A PC, OX A PB and OX = OY, prove that PB = PC. Solution: Given: O is the centre of the circle, OYAPC, OXAPB and OX = OY To prove: PB = PC Construction: O and P are joined Proof: (1) In 'POX and 'POY (i) ³ OXP = ³OYP (R) [Both are right angles] (ii) OP = OP (H) [Common side] (iii) OX=OY (S) [Given] (2) 'POX # 'POY [By R.H.S axiom] (3) PX = PY [Corresponding sides of congruent triangles] (4) AB = CD [OXAAB , OYACD and OX = OY] (5) BX = CX [From (4), AB = CD and OXAAB , OYACD] (6) PB = PC [Adding (3) and (5), PX+PB = PY+PC] 18. In the given figure, ABC is a triangle in which AB = AC. Also a circle passing through B and C intersects the sides AB and AC at the points D and E respectively. Prove that AD = AE. Solution: Given: In triangle ABC, AB = AC. The circle passing through B and C intersects the side AB and AC at D and E respectively. To prove: AD = AE Construction: OPAAD and OQACE are drawn Proof: (1) AB = AC [Given]  ³ ABC = ³ACB [From (1)]  ³ OBC = ³OCB [OB = OC, the radii]  ³ ABO = ³ACO [Subtracting (3) from (2)] (5) In 'POB and 'QOC (i) ³ OPB = ³OQC (A) [Both are right angles] (ii) ³ PBO = ³QCO (A) [From (4), ³ ABO = ³ACO] (iii) OB = OC (S) [Radii]  'POB # 'QOC [By A.A.S axiom] D A B P C X Y O D A B P C X Y O O D E B C A O D E B C A

135 Vedanta Excel in Mathematics Teachers' Manual - 9 (7) OP = OQ [Corresponding sides of congruent triangles] (8) BD = CE [OPABD , OQACE and OP = OQ] (9) AD = AE [Subtracting (8) from (1), AB – BD = AC - CE] 19. In the given figure, O is the centre of a circle, AB the diameter, AC the chord and OM A AC. Prove that: (i) OM // BC (ii) BC = 2 OM Solution: Given: O is the centre of circle, AB the diameter, AC the chord and OMAAC To prove: (i) OM//BC (ii) BC = 2 OM Proof: (1) AM = MC [OMAAC and OM bisects the chord AC] (2) OA =OB [Radii] (3) OM//BC and BC = 2 OM [OM joins the mid-points of AB and AC] 20. In the adjoining figure, P is the centre of a circle. If PQ // BC, prove that: (i) AC = 2AQ (ii) PQ A AC. Solution: Given: P is the centre of circle, AB the diameter, C is a point on the circumference and PQ//BC To prove: (i) AC = 2AQ (ii) PQAAC Proof: (1) AP = BP [Radii] (2) AQ = QC i.e., AC = 2AQ [In 'ABC; AP = BP and PQ//BC] (3) PQAAC [PQ joins the mid-point of chord AC and the centre of the circle] 21. In the given figure, two circles with centres P and Q intersect at A and B. Prove that the line joining the two centres o f the circles is the perpendicular bisector of the common chord. Solution: Given: Circles with centres P and Q intersect at A and B To prove: PQ is the perpendicular bisector of AB i.e., POAAB and OA = OB Construction: A and B are joined to P and Q Proof: (1) In 'PAQ and 'PBQ (i) AP = BP (S) [Radii of circle with centre P] (ii) AQ = BQ (S) [Radii of circle with centre Q] (iii) PQ = PQ (S) [Common side] (2) 'PAQ # 'PBQ [By S.S.S axiom] (3) ³APQ = ³BPQ [Corresponding angles of congruent triangles] (4) POAAB and OA = OB [In 'PAB, PA = PB and ³APQ = ³BPQ] O A B C M P C A B Q A B P Q A B P Q

Vedanta Excel in Mathematics Teachers' Manual - 9 136 22. In the given figure, P and Q be the centres of two intersecting circles and AB // PQ. Prove that AB = 2 PQ. Solution: Given: Circles with centres P and Q intersect at X and Y and AB//PQ To prove: AB = 2PQ Construction: PM AAX and QNABX are drawn Proof: (1) PQNM is a rectangle [AB//PQ and by construction] (2) AX = 2MX and BX=2NX [PM AAX, QNABX and bisect the AX and BX] (3) AB = AX+BX [Whole part axiom] (4) AB = 2(MX+NX)=2MN [From (2) and (3)] (5) AB=2PQ [From (4),MN = PQ; the opposite sides of rectangle] 23. In the given figure, two circles with centres P and Q are intersecting at A and B. If MN is parallel to common chord AB, prove that (i) MC = ND (ii) MD = NC Solution: Given: Circles with centres P and Q intersect at A and B and MN// AB To prove: (i) MC = ND (ii) MD = NC Construction: A and B are joined to P and Q Proof: (1) In 'PAQ and 'PBQ (i) AP = BP (S) [Radii of circle with centre P] (ii) AQ = BQ (S) [Radii of circle with centre Q] (iii) PQ = PQ (S) [Common side] (2) 'PAQ # 'PBQ [By S.S.S axiom] (3) ³APQ = ³BPQ [Corresponding angles of congruent triangles] (4) POAAB and OA = OB [In 'PAB, PA = PB and ³APQ = ³BPQ] (5) PQACD [From (4), AB//MN] (6) CX = DX [PXACD and PX bisects CD] (7) MX = NX [QXAMN and QX bisects MN] (8) MC = ND [Subtracting (6) from(7), MX – CX = NX – DX] (9) MD = NC [Adding CD in (8), MC + CD = ND + CD] 24. Prove that the diameter of a circle perpendicular to one of the two parallel chords of a circle is perpendicular to the other and bisects it. Solution: Given: O is the centre of circle, AB the diameter, chord PQ is perpendicular to the diameter AB and PQ//RS To prove: AB is perpendicular bisector of RS Proof: (1) ONARS [OMAPQ and PQ//RS] (2) RN = NS [ONARS and ON bisects RS] (3) AB is perpendicular bisector of RS [From(1) and (2)] A B X P Q A C B M N P Q D A C B M N P Q D A B O M P R S Q N A B X P M N Q

137 Vedanta Excel in Mathematics Teachers' Manual - 9 25. Prove that the line joining the mid-points of two parallel chords of a circle passes through the centre of the circle. Solution: Given: O is the centre of circle, AB//CD, M and N are the mid-points of the chords AB and CD respectively To prove: MN passes through the centre O Construction: P is a point such that PMAAB and O does not lie on PM Proof: (1) OMAAB [OM joins the mid-point of AB] (2) PMAAB [By assumption] (3) ³OMB = ³PMB [From (1) and (2)] (4) PM passes through O [From (3)] (5) ONACD and PNACD [ON joins the mid-point of CD and AB//CD] (6) MN passes through the centre O [From (4) and (5)] 26. Prove that a diameter of a circle which bisects a chord of the circle also bisects the angle subtended by the chord at the centre of the circle. Solution: Given: O is the centre of circle, AB is the diameter, CM = DM To prove: ³COM = ³DOM (1) In 'COM and 'DOM (i) OC = OD (S) [Radii of the circle] (ii) CM = DM (S) [Given] (iii) OM = OM (S) [Common side] (2) 'COM # 'DOM [By S.S.S axiom] (3) ³COM = ³DOM [Corresponding angles of congruent triangles] 27. Of two chords, the chord nearer to the centre of circle is longer. Solution: Given: O is the centre of circle; AB and CD are two chords such that AB > CD. OMAAB and ONACD To prove: OM < ON Construction: A and C are joined to O (1) AM = 1 2 AB and DN = 1 2 CD (2) OA2 = OM2 + AM2 and OD2 = ON2 + DN2 (3) OM2 + AM2 = ON2 + DN2 [From (2)] i.e., OM2 – ON2 = DN2 – AM2 (4) DN < AM or, DN2 < AM2 [AB > CD i.e., CD < AB and from (1)] (5) OM2 < ON2 or, OM < ON [From (3) and (4)] [OMAAB and OM bisects AB, ONACD and ON bisects CD] [Using Pythagoras theorem in rt. ³ed 'AOM and 'DON] O P M A C D B N O A C M D B O A M N C D B

Vedanta Excel in Mathematics Teachers' Manual - 9 138 28. Five students Amrit, Bibika, Chandani, Dipesh and Elina are playing in a circular meadow. Amrit is at the centre, Bibika and Dipesh are inside the boundary line. Similarly, Chandani and Elina are on the boundary of the meadow, If Amrit, Bibika, Chandani and Dipesh form a rectangle and the distance between Bibika and Dipesh is 10 m, find the distance between Amrit and Elina. Solution: (i) AC = BD = 10 m [Diagonals of rectangle are equal] (ii) AC = AE = 10 m [Radii of the circle] Hence, the distance between Amrit and Elina is 10 m. 29. Three students Pooja, Shaswat and Triptee are playing a game by standing on the circumference of a circle of radius 25 feet drawn in a park. Pooja throws a ball to Shaswat and Shaswat to Triptee and Triptee to Pooja. What is the distance between Pooja and Triptee when the distance between Pooja and Shaswat and the distance between Shaswat and Triptee is 30 feet each? Solution: Here, OP = OT = OS = 25 feet, PS = ST = 30 feet Since, OP = OT and PS = ST. So, OPST is a kite in which diagonal OS bisects the diagonal PT at M at a right angle. Let OM = x feet then MS = OS – OM = (25 – x) feet Now, From rt. ³ed 'OPM, PM2 = OP2 – OM2 = 252 – x2 = 625 – x2 ... (i) From rt. ³ed 'PMS, PM2 = PS2 – MS2 = 302 – (25 – x)2 = 900 – (625 – 50x + x2 ) = 275 + 50x – x2 ... (ii) From (i) and (ii), we get 625 – x2 = 275 + 50x – x2 ?x = 7 Also, from (i); PM2 = = 625 – 72 = 576 ?PM = 24 feet Again, PT = 2×PM = 2×24 feet = 48 feet Hence, the distance between Pooja and Triptee is 48 feet. 30. The diameter of a circular ground with centre at O is 200 m. Two vertical poles P and Q are fixed at the two points in the circumference of the ground. Find the length of a rope required to tie the poles tightly at a distance of 60 m from the centre of the ground. Solution: Let the poles P and Q are fixed at the points A and B on the circumference and OCAAB. Then the required length of rope to tie the poles is AB. and diameter = 200 m ?radius = OA = OB = 100 m and OC = 60 m Now, From rt. ³ed 'OBC, BC2 = OB2 – OC2 = 1002 – 602 = 6400 ?BC = 80 m Also, AB = 2BC = 2×80m = 160 m [OCAAB and OC bisects AB] 31. In the adjoining figure, OAB is an isosceles triangle and a circle with O as the centre cuts AB at C and D. Prove that AC = DB. Solution: Given: O is the centre of circle; OAB is an isosceles triangle C A E D 10m B P O T S P O T S M O A 100m 60m Q P C B A C D B O

139 Vedanta Excel in Mathematics Teachers' Manual - 9 To prove: AC = BD Construction: OMAAB is drawn Proof: (1) In 'AOM and 'BOM (i) ³OMA = ³OMB (A) [Both are right angles] (ii) ³OAM = ³OBM (A) [Base angles of isosceles triangle] (iii) OA = OB (S) [Given]  'AOM # 'BOM [By A.A.S axiom] (3) AM = BM [Corresponding sides of congruent triangles] (4) CM = BD [OMACD and OM bisects CD] (5) AC = BD [Subtracting (4) from (3), AM – CM = BM – BD] 32. In the figure alongside, MN is the diameter of a circle with centre O. If BD = CD, prove that ‘ OAD = ‘ OCD. Solution: Given: O is the centre of circle; MN is the diameter, BD = CD To prove: ³OAD = ³OCD Construction: O and B are joined Proof: (1) In 'COD and 'BOD (i) OC = OB (S) [Radii of the circle] (ii) OD = OD (S) [Common side] (iii) CD= BD (S) [Given] (2) 'COD # 'BOD [By S.S.S axiom] (3) ³OCD = ³OBD [Corresponding angles of congruent triangles] (4) ³OAD = ³OBD [OA = OB] (5) ³OAD = ³OCD [From (3) and (4)] 33. In the figure alongside, A and B are the centres of two intersecting circles. If CD intersects AB perpendicularly at P, prove that (i) CM = DN (ii) CN = DM Solution: Given: A and B are the centres of the intersecting circles. CD intersects AB perpendicularly To prove: (i) CM = DN (ii) CN = DM Proof: (1) PM = PN [APAMN and AP bisects MN] (2) PC = PD [BPACD and BP bisects CD] (3) CM = DN [Subtracting (1) from (2); PC – PM = PD – PN] (4) CN = DM [Adding MN in (3), CM + MN = DN + MN] M A C N B O D A C D B O M M A C N B O D A M C P N D B

Vedanta Excel in Mathematics Teachers' Manual - 9 140 Unit 15 Geometry - Construction Allocated teaching periods 5 Competency - To construct square, rectangle, rhombus, parallelogram, quadrilateral and trapezium and analyze them. Learning Outcomes - To construct square, rectangle, rhombus, parallelogram, quadrilateral and trapezium. Level-wise learning objectives S.N. LEVELS OBJECTIVES 1. Application (A) - To sketch the rough figure and construct square, rectangle, rhombus, parallelogram, quadrilateral and trapezium under the given information Required Teaching Materials/ Resources Geometric instruments, geo-board, pencils, marker, ICT tool etc. Pre-knowledge: properties of square, rectangle, rhombus, parallelogram, quadrilateral and trapezium. Teaching Activities 1. Discuss about the procedures of constructions of square and give the different side / diagonal lengths of squares to construct in groups. 2. Discuss about the procedures of constructions of rectangle and rhombus and give the different information to construct in groups. 3. Explain the constructions procedures of quadrilateral and give the different information to construct in groups. 4. Explain the constructions procedures of trapezium and give the different information to construct in groups. Solution of selected problems from Vedanta Excel in Mathematics 1. Construct a parallelogram ABCD in which diagonals AC = 4.6 cm, BD = 5.8 cm and they bisect each other making an angle of 30q. Steps of construction (i) Draw a diagonal AC = 4.6 cm, (ii) Draw the perpendicular bisector of AC and mark its mid-point O. (iii) At O, construct ‘AOX = 30q and produce XO to Y. (iv) Here, O is also the mid-point of BD. With centre at O and radius OB = OD = 2.9 cm ( 1 2 of BD) cut OY at B and OX at D. v) Join A, D; B, C; A, B and C, D. Thus, ABCD is the required parallelogram. X D A C B Y O

141 Vedanta Excel in Mathematics Teachers' Manual - 9 2. Construct a trapezium ABCD in which AB = 5.5 cm, BC = 4.5 cm, ‘DAB = 45q, ‘BCD = 60q and AD // BC. Steps of construction (i) Draw a line segment AB = 5.5 cm. (ii) Construct ‘BAX = 45q at A. (iii) D lies on AX and AD // BC. So, at B, construct ‘ABY = 180q – 45q = 135q (iv) With the centre at B and radius 4.5 cm draw an arc to cut BY at C. (v) At C, construct ‘BCD = 60q. The arm CD intersect AX at D. Thus, ABCD is the required trapezium. 3. Construct a trapezium ABCD in which AB = 4.8 cm, diagonal AC = 5.9 cm, ‘BAC = 60q, CD = 5 cm and AB // DC. Steps of construction (i) Draw a line segment AB = 4.8 cm. (ii) At A, construct ‘BAX = 60q. (iii) With centre at A and radius 5.9 cm, draw an arc to cut AX at C. (iv) Join B and C. (v) As AB // DC, alternate angles BAC and ACD are equal. So, construct ‘ACY = 60q at C. (vi) With centre at C and radius 5 cm, draw an arc to cut CY at D. (vii) Join D and A. Thus, ABCD is the required trapezium. 4. Construct a trapezium ABCD in which AB = 4.4 cm, diagonal AC = 6.8 cm, AD = BC = 5.2 cm and AB // DC. Steps of construction (i) Draw a line segment AB = 4.4 cm. (ii) With centre at A and radius 6.8 cm, draw an arc. (iii) With centre at B and radius 5.2 cm, draw another arc to intersect the previous arc at C. D X 60° 45° A B C Y A B X Y 60° 60° D C

Vedanta Excel in Mathematics Teachers' Manual - 9 142 (iv) Join A, C and B, C. (v) At C, construct ‘ACX = ‘BAC. (vi) With centre at A and radius 5.2 cm, draw an arc to cut CX at D. (vii) Join A and D. Thus, ABCD is the required trapezium. 5. Construct a quadrilateral ABCD in which AB = 5 cm, BC = 5.6 cm, CD = 4.5 cm, AD = 5.4 cm and the diagonal BD = 6.5 cm. Steps of construction (i) Draw AB = 5 cm. (ii) From A, draw an arc with radius AD = 5.4 cm and from B draw another arc with radius BD = 6.5 cm. These two arcs intersect each other at D. (iii) From B, draw an arc with radius BC = 5.6 cm and from D, draw another arc with radius DC = 4.5 cm. These two arcs intersect to each other at C. Join A, D; B, C and D, A. Thus, ABCD is the required quadrilateral. X D C A B D 4.5 cm 5cm 5.6 cm 5.4 cm C B A 6.5 cm

143 Vedanta Excel in Mathematics Teachers' Manual - 9 Unit 16 Trigonometry Allocated teaching periods 7 Competency - To solve the related problem based on trigonometric ratios. Learning Outcomes - To introduce trigonometric ratios - To verify the fundamental trigonometric ratios from the right angled triangle for the given reference angle - To find the trigonometric ratios of some standard angles - To solve the right angled triangle by using trigonometric ratios Level-wise learning objectives S.N. LEVELS OBJECTIVES 1. Knowledge (K) - To define trigonometry - To tell the six trigonometric ratios - To identify the trigonometric ratio based on the reference angle and given sides - To tell the trigonometric ratios of some standard angles 2. Understanding (U) - To find the trigonometric ratios of given reference angle in terms of sides of the right angled triangle - To convert a trigonometric ratio in to another - To find the value of expression involving trigonometric ratios with standard angles - To find the unknown length of side of triangle when reference angle is a standard angle 3. Application (A) - To verify the fundamental trigonometric ratios from the right angled triangle for the given reference angle - To find the trigonometric ratios of some standard angles from right angled triangle - To solve the right angled triangle by using trigonometric ratios 4. High Ability (HA) - To prepare a report on investigating the application of trigonometry, ratios and identities Required Teaching Materials/ Resources Colourful chart-paper, models of right angled triangles, geometric instruments, colourful markers, chart paper with trigonometric ratios of standard angles up to 900, ICT tool etc

Vedanta Excel in Mathematics Teachers' Manual - 9 144 Pre-knowledge: right angled triangles, Pythagorean triplets and name of parts its sides Teaching Activities 1. Recall Pythagorean triplets with examples 2. Show a right angled triangle and ask to identify its hypotenuse, base and perpendicular 3. Discuss about perpendicular, hypotenuse and base in right angled triangle with respect to one of the acute angle as the reference angle 4. Ask the students to make the possible ratios of perpendicular (p), base (b) and hypotenuse (h) then explain about following six trigonometric ratios (i) sinT = p h (ii) cosT = b h (iii) tanT = p b (iv) cosecT = h p (v) secT = h b (vi) cotT = b p 5. Divide the students in to 5 groups. Give them the right angled triangles with different names and ask to identify the perpendicular, base and hypotenuse. Also, ask them to express all six trigonometric ratios in terms of sides of the triangles 6. With discussion, give guidelines to solve the problems given in the textbooks. 7. Discuss on establishing the relationships of trigonometric ratios 8. With discussion, explain the trigonometric ratios of some standard angles up to 900 9. Tell the students to draw the table of trigonometric ratios of standard angles on a chart paper and past on the mathematics corner of the classroom or mathematics lab as project work. 10. Encourage the students to evaluate the trigonometric expressions involving the standard angles 11. Discuss on the solution of right angles triangles which is supportive for the next class to solve the problems related to height and distance Solution of selected problems from Vedanta Excel in Mathematics 1) If sin (90° − D) = BC CA , write down the ratio of sinD. Solution: Here, Sin (90° − D) = BC CA = p b ? For reference angle (90° − D) Perpendicular (p) = BC and hypotenus (h) = CA Also, ‘C =90° − (90° − D) = D For reference angle D, perpendicular (p) = AB, base (b) = BC and hypotenuse (h) = CA ? SinD = p' h' = AB CA 2) From the adjoining figure, show that tanE = 4 3 . Solution: i) In rt. angled ∆XYZ. XY = XZ2 – YZ2 = 262 – 242 = 10 ft A B C C B 90°D A E X Y Z 24 ft 26 ft 6 ft W

145 Vedanta Excel in Mathematics Teachers' Manual - 9 ii) In rt. angled ∆XYZ, WY = XY2 – XW2 = 102 – 62 = 8 ft ? tanE = WY(p) XW(b) =8 ft 6 ft = 4 3 3) In the adjoining figure ABCD is a rhombus in which AC = 6 cm, BD = 8 cm and ‘ADC = T. Find the values of sinT and tanT. Solution: i) OA = 1 2 AC = 1 2 u 6 cm = 3 cm OD = 1 2 BD = 1 2 u 8 cm = 4 cm ( Diagonal of rhombus do bisect each other at a right angle ) and ‘AOD = 90° ii) In rt.angled 'AOD; AD = OA2  OD2 = 32  42 = 5 cm ? sinT = OA(p) AD(h) = 3 5 and tanT = OA(p) OD(b) = 3 4 4) In the circle given alongside, O is the centre, M is the mid - point of chord AB. If AB = 12 cm and CM = 8 cm and ‘OAM = T, find the values of sinT and cosT. Solution: i) AM = 1 2 AB = 1 2 u 12 cm = 6 cm ii) OM A AB [OM joins the centre O and the mid - point M of the chords AB. iii) In rt. angled 'AOM; AO = OM2  AM2 = 82  62 = 10 cm ? sinT = OM(p) OA(h) = 8 cm 10 cm = 4 5 , cosT = AM OA = 6 cm 10 cm = 3 5 5) In the adjoining figure, AB = 6, BC = 8 cm, ‘ABC = 90°, BD A AC and ‘ABD = T. Find the value of sinT. Solution: i) In rt ‘ed ∆ ABC, AC = AB2 + BC2 = 62 + 82 = 10 ii) In ∆ ABC and ∆ ABD, (a) ‘ABC = ‘BDA [Both are right angles] (b) ‘BAC = ‘BAD [Common angle] (c) ‘ACB = ‘ABD [Remaining angles]  ?'ABC ~ 'ABD iii) AC AB = BC BD = AB AD [corresponding angles of similar angle] or, 10 6 = 8 BD = 6 AD A D C O T B O A M B T

Vedanta Excel in Mathematics Teachers' Manual - 9 146 From 1st and 2nd ratios, we get 10 6 = 8 BD ? BD = 24 5 From 1st and 3rd ratios, we get 10 6 = 6 AD ? AD = 18 5 iv) In 1st angled 'ABD, sinT = AD(p) AB(h) = 18/5 4 = 3 5 6) In the given 'ABC, ‘B = 90°, and ‘CAB = 45°. If AB = x cm. Prove that sin 45° = 1 Solution: 2 Given: In 'ABC, ‘B = 90°, and ‘ACB = 45°, AB = x cm To prove: sin 45° = 1 2 Proof: i) ‘ACB = 180q  (‘A  ‘B) = 180°  (45q  90q) = 45q ii) AB = BC [‘A = ‘C = 45q] iii) AC = AB2  BC2 = x2  x2 = 2x cm [By using pythagoras theorem] iv) In rt.angled 'ABC; sin 45q = BC AC = x 2x = 1 2 7) In the adjoining equilateral 'ABC, AD A BC and AC = 2a units. Prove that sin 60q = 3 2 Solution: Given: ABC is an equilateral triangle. AD A BC and AC = 2a units. To prove: sin 60° = 3 2 Proof: i) ‘C = 60q [Being an angle of equilateral triangle] ii) CD = 1 2 BC = 1 3 u 2a = a [Median of equilateral ' bisects its base] iii) In rt. ‘ed 'ABC; AD = AC2  CD2 = (2a) 2  a2 = 3a cm [By Pythagorom theorem] iv) sin60q = AD(p) AC(h) = 3a 2 = 3 2 ? sin60q = 3 2 proved 8) In the given figure, ABCD is a square and ‘CPM = 90q, if CM = 4 cm, PD = 3 cm. Find the side of square. Solution: i) In rt. angled 'CMP; cos30q = PC(b) CM(h) = 3 2 = CP 4 ? CP = 2 3 cm ii) In rt. angle 'PCD; CD = CP2  DP2 = (2 3) 2  ( 3) 2 = 3 cm Hence, the side of square ABCD is 3 cm. C B A 45q A D C 2a B 30q A M P D B C