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Edexcel AS and A level Mathematics Pure Mathematics Year 1 /AS Series Editor: Harry Smith Authors: Greg Attwood, Jack Barraclough, Ian Bettison, Alistair Macpherson, Bronwen/uni00A0Moran, Su Nicholson, Diane Oliver, Joe Petran, Keith Pledger, Harry Smith, Geoff /uni00A0Staley, Robert Ward-Penny, Dave Wilkins11 – 19 PROGRESSION
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Edexcel AS and A level Mathematics Pure Mathematics Year 1 /AS Series Editor: Harry Smith Authors: Greg Attwood, Jack Barraclough, Ian Bettison, Alistair Macpherson, Bronwen/uni00A0Moran, Su Nicholson, Diane Oliver, Joe Petran, Keith Pledger, Harry Smith, Geoff /uni00A0Staley, Robert Ward-Penny, Dave Wilkins11 – 19 PROGRESSION
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iiContents Overarching themes iv Extra online c ontent vi 1 Algebraic e xpressions 1 1.1 Index law s 2 1.2 Expanding brack ets 4 1.3 Factorising 6 1.4 Negative and fractional indic es 9 1.5 Surds 12 1.6 Rationalising denominators 13 Mixed ex ercise 1 15 2 Quadratics 18 2.1 Solving quadratic equations 19 2.2 Completing the squar e 22 2.3 Functions 25 2.4 Quadratic graphs 27 2.5 The discriminant 30 2.6 Modelling with quadratics 32 Mixed ex ercise 2 35 3 Equations and inequalities 38 3.1 Linear simultaneous equations 39 3.2 Quadratic simultaneous equations 41 3.3 Simultaneous equations on graphs 42 3.4 Linear inequalities 46 3.5 Quadratic inequalities 48 3.6 Inequalities on graphs 51 3.7 Regions 53 Mixed ex ercise 3 56 4 Graphs and trans formations 59 4.1 Cubic graphs 60 4.2 Quartic graphs 64 4.3 Reciprocal gr aphs 66 4.4 Points of int ersection 68 4.5 Translating gr aphs 71 Contents 4.6 Stretching graphs 75 4.7 Trans forming functions 79 Mixed ex ercise 4 82 Review ex ercise 1 85 5 Straight line gr aphs 89 5.1 y = mx + c 90 5.2 Equations of st raight lines 93 5.3 Parall el and perpendicular lines 97 5.4 Length and area 100 5.5 Modelling with straight lines 103 Mixed ex ercise 5 108 6 Circles 113 6.1 Midpoints and perpendicular bisectors 114 6.2 Equation of a cir cle 117 6.3 Intersections of st raight lines and circles 121 6.4 Use tangent and chord pr operties 123 6.5 Circles and t riangles 128 Mixed ex ercise 6 132 7 Algebraic methods 137 7.1 Algebraic fr actions 138 7.2 Dividing polynomials 139 7.3 The factor theorem 143 7.4 Mathematical proof 146 7.5 Methods of proo f 150 Mixed ex ercise 7 154 8 The binomial expansion 158 8.1 Pascal ’s triangle 159 8.2 Factorial notation 161 8.3 The binomial expansion 163 8.4 Solving binomial problems 165
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iiiContents 8.5 Binomial estimation 167 Mixed ex ercise 8 169 9 Trigonometric r atios 173 9.1 The cosine rul e 174 9.2 The sine rule 179 9.3 Areas o f triangles 185 9.4 Solving triangle pr oblems 187 9.5 Graphs of sine, c osine and tangent 192 9.6 Trans forming trigonometric graphs 194 Mixed ex ercise 9 198 10 Trigonometric identities and equations 202 10.1 Angles in all four quadr ants 203 10.2 Exact values o f trigonometrical ratios 208 10.3 Trigonomet ric identities 209 10.4 Simple trig onometric equations 213 10.5 Harder trig onometric equations 217 10.6 Equations and identities 219 Mixed ex ercise 10 222 Review ex ercise 2 226 11 Vectors 230 11.1 Vectors 231 11.2 Representing v ectors 235 11.3 Magnitude and direction 239 11.4 Position v ectors 242 11.5 Solving geometric pr oblems 244 11.6 Modelling with vectors 248 Mixed ex ercise 11 251 12 Differentiation 255 12.1 Gradients of cur ves 256 12.2 Finding the derivative 259 12.3 Differentiating xn 262 12.4 Differentiating quadr atics 26412.5 Differentiating functions with t wo or more terms 266 12.6 Gradients, tang ents and normal 268 12.7 Increasing and decr easing functions 270 12.8 Second order deriv atives 271 12.9 Stationary points 273 12.10 Sketching gr adient functions 277 12.11 Modelling with differentiation 279 Mixed ex ercise 12 282 13 Integration 287 13.1 Integr ating xn 288 13.2 Indefinite integr als 290 13.3 Finding functions 293 13.4 Definite integr als 295 13.5 Areas under cur ves 297 13.6 Areas under the x-axis 300 13.7 Areas bet ween curves and lines 302 Mixed ex ercise 13 306 14 Exponentials and logarithms 311 14.1 Exponential functions 312 14.2 y = ex 314 14.3 Exponential modelling 317 14.4 Logarithms 319 14.5 Law s of logarithms 321 14.6 Solving equations using logarithms 324 14.7 Working with natur al logarithms 326 14.8 Logarithms and non-linear data 328 Mixed ex ercise 14 334 Review ex ercise 3 338 Practic e exam paper 342 Answ ers 345 Index 399
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ivOverarching themes The following three overarching themes have been fully integrated throughout the Pearson Edexcel AS and A level Mathematics series, so they can be applied alongside your learning and practice. 1. Mathematical argument, language and proof β€’ Rigorous and consistent approach throughoutβ€’ Notation boxes explain key mathematical language and symbolsβ€’ Dedicated sections on mathematical proof explain key principles and strategiesβ€’ Opportunities to critique arguments and justify methods 2. Mathematical problem solving β€’ Hundreds of problem-solving questions, fully integrated into the main exercises β€’ Problem-solving boxes provide tips and strategiesβ€’ Structured and unstructured questions to build confi denceβ€’ Challenge boxes provide extra stretch 3. Mathematical modelling β€’ Dedicated modelling sections in relevant topics provide plenty of practice where you need it β€’ Examples and exercises include qualitative questions that allow you to interpret answers in the context of the model β€’ Dedicated chapter in Statistics & Mechanics Year 1/AS explains the principles of modelling in mechanics Overarching themes Each chapter starts with a list of objectives The Prior knowledge check helps make sure you are ready to start the chapterThe real world applications of the maths you are about to learn are highlighted at the start of the chapter with links to relevant questions in the chapterFinding your way around the book Access an online digital edition using the code at the front of the book.The Mathematical Problem-solving cycle specify the problem interpret resultscollect information process and represent information
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vOverarching themes Every few chapters a Review exercise helps you consolidate your learning with lots of exam-style questionsEach section begins with explanation and key learning points Step-by-step worked examples focus on the key types of questions you’ll need to tackleExercise questions are carefully graded so they increase in diffi culty and gradually bring you up to exam standard Problem-solving boxes provide hints, tips and strategies, and Watch out boxes highlight areas where students oft en lose marks in their examsExercises are packed with exam-style questions to ensure you are ready for the exams A full AS level practice paper at the back of the book helps you prepare for the real thing Exam-style questions are fl agged with Problem-solving questions are fl agged withE PEach chapter ends with a Mixed exercise and a Summary of key pointsChallenge boxes give you a chance to tackle some more diffi cult questions
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viExtra online content Whenever you see an Online box, it means that there is extra online content available to support you. SolutionBank SolutionBank provides a full worked solution for every question in the book. Download all the solutions as a PDF or quickly fi nd the solution you need online Extra online content Full worked solutions are available in SolutionBank.Online
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viiExtra online content Access all the extra online content for FREE at: www.pearsonschools.co.uk/p1maths You can also access the extra online content by scanning this QR Code: GeoGebra interactives Explore topics in more detail, visualise problems and consolidate your understanding with GeoGebra-powered interactives. Interact with the maths you are learning using GeoGebra's easy-to-use tools Explore the gradient of the chord AP using GeoGebra.Online Casio calculator support Our helpful tutorials will guide you through how to use your calculator in the exams. They cover both Casio's scientific and colour graphic calculators. See exactly which buttons to press and what should appear on your calculator's screen Work out each coefficient qui ckly using the nCr and power functions on your calculator.Online
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viiiPublished by Pearson Education Limited, 80 Strand, London WC2R 0RL. www.pearsonschoolsandfecolleges.co.uk Copies of official specifications for all Pearson qualifications may be found on the website: qualifications.pearson.com Text Β© Pearson Education Limited 2017 Edited by Tech-Set Ltd, GatesheadTypeset by Tech-Set Ltd, GatesheadOriginal illustrations Β© Pearson Education Limited 2017 Cover illustration Marcus@kja-artists The rights of Greg Attwood, Jack Barraclough, Ian Bettison, Alistair Macpherson, Bronwen Moran, Su Nicholson, Diane Oliver, Joe Petran, Keith Pledger, Harry Smith, Geoff Staley, RobertΒ Ward -Penny, Dave Wilkins to be identified as authors of this work have been asserted by them in accordance with the Copyright, Designs and Patents Act 1988. First published 201720 19 18 17 10 9 8 7 6 5 4 3 2 1 British Library Cataloguing in Publication Data A catalogue record for this book is available from the British Library ISBN 978 1 292 20826 8 (Print) Copyright notice All rights reserved. No part of this publication may be reproduced in any form or by any means (including photocopying or storing it in any medium by electronic means and whether or not transiently or incidentally to some other use of this publication) without the written permission of the copyright owner, except in accordance with the provisions of the Copyright, Designs and Patents Act 1988 or under the terms of a licence issued by the Copyright Licensing Agency, Barnards Inn 86 Fetter Lane, London EC4A 1EN (www.cla.co.uk). Applications for the copyright owner’s written permission should be addressed to the publisher. Printed in Slovakia by NeografiaPicture Credits The publisher would like to thank the following for their kind permission to reproduce their photographs: (Key: b-bottom; c-centre; l-left; r-right; t-top)123RF.com: David Acosta Allely 287, 338cr; Alamy Images: Utah Images 113, 226l, Xinhua 38, 85cr, ZUMA Press, Inc. 311, 338r; Fotolia.com: Kajano 137, 226cl, sborisov 173, 226r, Thaut Images 202, 226tr; Getty Images: Graiki 255, 338cl, Henglein and Steets 18, 85c, Jeff Schultz 230, 338l, mviamonte 1, 85l, Steve Dunwell 158, 226cr; Science Photo Library Ltd: CMS EXPERIMENT, CERN 59, 85; Shutterstock.com: vladimir salman 89, 226tl All other images Β© Pearson EducationISBN 978 1 292 20759 9 (PDF)
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1 Algebraic expressions After completing this chapter you should be able to: ● Multiply and divide integer po wers β†’ pages 2–3 ● Expand a single term over brackets and collect like terms β†’ pages 3–4 ● Expand the product of two or three expressions β†’ pages 4–6 ● Factorise linear, quadratic and simple cubic expressions β†’ pages 6–9 ● Know and use the laws of indices β†’ pages 9–11 ● Simplify and use the rules of surds β†’ pages 12–13 ● Rationalise denominators β†’ pages 13–16Objectives 1 Simplify: a 4m2n + 5mn2 – 2m2n + mn2 – 3mn2 b 3x2 – 5x + 2 + 3x2 – 7x – 12 ← GCSE Mathematics 2 Write as a single power of 2:a 25 Γ— 23 b 26 Γ· 22 c (23)2 ← GCSE Mathematics 3 Expand:a 3(x + 4) b 5(2 – 3 x) c 6(2x – 5y) ← GCSE Mathematics 4 Write down the highest common factor of:a 24 and 16 b 6x and 8x2 c 4xy2 and 3xy ← GCSE Mathematics 5 Simplify: a 10x ____ 5 b 20x ____ 2 c 40x ____ 24 ← GCSE MathematicsPrior knowledge check Computer scientists use indices to describe very large numbers. A quantum computer with 1000 qubits (quantum bits) can consider 2 1000 values simultaneously. This is greater than the number of particles in the observable universe.1
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2 Chapter 1 1.1 Index laws β–  You can use the laws of indices to simplify powers of the same base. β€’ am Γ— an = am + n β€’ am Γ· an = am βˆ’ n β€’ (am)n = amn β€’ (ab)n = anbn Example 1 Example 2 Expand these expressions and simplify if possible: a –3x (7x – 4) b y2(3 – 2y3) c 4x (3x – 2x2 + 5x3) d 2x (5x + 3) – 5(2x + 3)Simplify these expressions:a x2 Γ— x5 b 2r2 Γ— 3r3 c b7 __ b4 d 6x5 Γ· 3x3 e (a3)2 Γ— 2a2 f (3x2)3 Γ· x4 x5Notation This is the base . This is the index, power or exponent. a x2Β Γ—Β x5 =Β x2 + 5 =Β x7 b 2r2Β Γ—Β 3 r3 =Β 2Β Γ— Β 3Β Γ—Β r2Β Γ—Β r3 =Β 6Β Γ—Β r2 + 3 =Β 6 r5 c b7 __ b4 = b7 βˆ’ 4 =Β b3 d 6x5Β Γ·Β 3 x3 =Β  6 __ 3 Β Γ—Β  x5 ____ x3 =Β 2Β Γ— Β x2 = 2x2 e (a3)2Β Γ—Β 2 a2 =Β a6Β Γ—Β 2 a2 =Β 2Β Γ—Β a6Β Γ—Β a2 =Β 2 a8 f (3x2)3 _____ x4 =Β 33 Γ— (x2)3 ____ x4 = 27 Γ— x6 __ x4 =Β  27 x2Use the rule amΒ Γ—Β anΒ =Β am + n to simplify the index. x5Β Γ·Β x3Β =Β x5 βˆ’ 3Β =Β x2Rewrite the expression with the numbers together and the r terms together. 2Β Γ—Β 3Β =Β 6 r2Β Γ—Β r3Β =Β r2 + 3 A min us sign outside brackets changes the sign of every term inside the brackets.Watch outUse the rule am Γ· an = am βˆ’ n to simplify the index. Use the rule (am)nΒ =Β amn to simplify the index. a6Β Γ— a2 = a6 + 2 = a8 Use the rule (ab)nΒ =Β anbn to simplify the numerator. (x2)3Β =Β x2 Γ— 3Β =Β x6 x6 __ x4 Β =Β x6 βˆ’ 4Β =Β x2
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3Algebraic expressions a βˆ’3x(7xΒ βˆ’ 4 ) =Β βˆ’21x2Β +Β 12 x b y2(3Β βˆ’Β 2y3) =Β 3 y2Β βˆ’Β 2y5 c 4x(3xΒ βˆ’Β 2 x2Β +Β 5 x3) =Β 12 x2Β βˆ’Β 8 x3Β +Β 20 x4 d 2x(5xΒ +Β 3 )Β βˆ’Β 5(2 xΒ +Β 3) =Β 10 x2Β +Β 6 xΒ βˆ’Β 10 xΒ βˆ’Β 15 =Β 10 x2Β βˆ’Β 4 xΒ βˆ’Β 15 a x7 + x4 _______ x3 = x7 ___ x3 + x4 ___ x3 = x7 – 3Β + x4 βˆ’ 3 = x4Β + x b 3x2 βˆ’ 6x5 __________ 2x = 3 x 2 ____ 2x βˆ’ 6 x 5 ____ 2x = 3 __ 2 x 2 – 1 – 3x5 – 1 = 3x ___ 2 βˆ’ 3 x 4 c 20x7 + 15x3 ____________ 5x2 = 20 x 7 _____ 5 x 2 + 15 x 3 _____ 5 x 2 = 4x7 – 2 + 3 x3 – 2 = 4 x 5 + 3 xExample 3βˆ’3xΒ Γ—Β 7xΒ ξ€΅Β βˆ’21x1 +Β 1Β ξ€΅Β βˆ’21x2 βˆ’3xΒ Γ—Β (βˆ’4)  12x Remember a minus sign outside the brackets changes the signs within the brackets. Simplify 6xΒ βˆ’Β 10x to give βˆ’4x. Simplify these expressions: a x 7 + x 4 ______ x 3 b 3 x 2 βˆ’ 6 x 5 ________ 2x c 20 x 7 + 15 x 3 __________ 5 x 2 y2Β Γ—Β (βˆ’2y3)Β ξ€΅Β βˆ’2y2 +Β 3Β ξ€΅Β βˆ’2y5 Divide each term of the numerator by x 3 . x1 is the same as x. Divide each term of the numerator by 2x. Simplify each fraction: 3 x 2 ____ 2x = 3 __ 2 Γ— x 2 ___ x = 3 __ 2 Γ— x2 βˆ’ 1 βˆ’ 6 x 5 ____ 2x = βˆ’ 6 __ 2 Γ— x 5 ___ x = βˆ’3 Γ— x5 βˆ’ 1 Divide each term of the numerator by 5x2. 1 Simplify these expressions: a x3 Γ— x4 b 2x3 Γ— 3x2 c k3 __ k2 d 4p3 ___ 2p e 3x3 ___ 3x2 f (y2)5 g 10x5 Γ· 2x3 h ( p3)2 Γ· p4 i (2a3)2 Γ· 2a3 j 8p4 Γ· 4p3 k 2a4 Γ— 3a5 l 21a3b7 ______ 7ab4 m 9x2 Γ— 3(x2)3 n 3x3 Γ— 2x2 Γ— 4x6 o 7a 4 Γ— (3a 4)2 p (4y 3)3 Γ· 2y3 q 2a3 Γ· 3a2 Γ— 6a5 r 3a4 Γ— 2a5 Γ— a3Exercise 1A
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4 Chapter 1 1.2 Expanding brackets To find the product of two expressions you multiply each term in one expression by each term in the other expression. (x + 5)(4x – 2y + 3)x Γ— 5 Γ—= x(4x – 2y + 3) + 5(4x – 2y + 3)= 4x 2 – 2xy + 3x + 20x – 10y + 15 = 4x2 – 2xy + 23x – 10y + 15Multiplying each of the 2 terms in the first expression by each of the 3 terms in the second expression gives 2 Γ— 3 = 6 terms. Simplify your answer by collecting like terms.2 Expand and simplify if possible: a 9(x βˆ’ 2) b x(x + 9) c βˆ’3y (4 βˆ’ 3y) d x(y + 5) e βˆ’x(3 x + 5) f βˆ’5x (4x + 1) g (4x + 5)x h βˆ’3y (5 βˆ’ 2y2) i βˆ’2x (5x βˆ’ 4) j (3x βˆ’ 5)x2 k 3(x + 2) + (x βˆ’ 7) l 5x βˆ’ 6 βˆ’ (3x βˆ’ 2) m 4(c + 3d 2) βˆ’ 3(2c + d 2) n (r2 + 3t2 + 9) βˆ’ (2r2 + 3t2 βˆ’ 4) o x(3x2 βˆ’ 2x + 5) p 7y2(2 βˆ’ 5y + 3y2) q βˆ’2y2(5 βˆ’ 7y + 3y2) r 7(x βˆ’ 2) + 3(x + 4) βˆ’ 6(x βˆ’ 2) s 5x βˆ’ 3(4 βˆ’ 2x) + 6 t 3x2 βˆ’ x(3 βˆ’ 4x) + 7 u 4x( x + 3) βˆ’ 2x(3x βˆ’ 7) v 3x2(2x + 1) βˆ’ 5x2(3x βˆ’ 4) 3 Simplify these fractions: a 6 x 4 + 10 x 6 _________ 2x b 3 x 5 βˆ’ x 7 _______ x c 2 x 4 βˆ’ 4 x 2 ________ 4x d 8 x 3 + 5x ________ 2x e 7 x 7 + 5 x 2 ________ 5x f 9 x 5 βˆ’ 5 x 3 ________ 3x a (x + 5)(x + 2) = x2 + 2x + 5 x + 10 = x2 + 7x + 10 b (x βˆ’ 2y)(x2 + 1) = x3 + x βˆ’ 2x2y βˆ’ 2 yExample 4 Expand these expressions and simplify if possible: a (x + 5)(x + 2) b (x βˆ’ 2y)(x2 + 1) c (x βˆ’ y)2 d (x + y)(3x βˆ’ 2y βˆ’ 4) Multiply x by (x + 2) and then multiply 5 by (x + 2). Simplify your answer by collecting like terms. βˆ’2y Γ— x2 = βˆ’2x2y There are no like terms to collect.
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5Algebraic expressions c (x βˆ’ y)2 = (x βˆ’ y)(x βˆ’ y) = x2 βˆ’ xy βˆ’ xy + y2 = x2 βˆ’ 2xy + y2 d (x + y)(3x βˆ’ 2 y βˆ’ 4) = x(3x – 2y – 4) + y (3x – 2 y – 4) = 3x2 βˆ’ 2xy βˆ’ 4 x + 3 xy βˆ’ 2 y2 βˆ’ 4y = 3x2 + xy βˆ’ 4 x βˆ’ 2 y2 βˆ’ 4y a x(2x + 3)(x βˆ’ 7) = (2x2 + 3 x)(x βˆ’ 7) = 2 x3 βˆ’ 14 x2 + 3 x2 βˆ’ 21x = 2 x3 βˆ’ 11 x2 βˆ’ 21x b x(5x βˆ’ 3y)(2x βˆ’ y + 4) = (5x2 βˆ’ 3 xy)(2x βˆ’ y + 4) = 5x2(2x – y + 4) – 3 xy(2x – y + 4) = 10x3 βˆ’ 5 x2y + 20 x2 βˆ’ 6 x2y + 3 xy2 βˆ’ 12 xy = 10 x3 βˆ’ 11 x2y + 20 x2 + 3 xy2 βˆ’ 12 xy c (x βˆ’ 4)( x + 3)( x + 1) = (x2 βˆ’ x βˆ’ 12)( x + 1) = x2(x + 1) – x (x + 1) – 12( x + 1) = x3 + x2 βˆ’ x2 βˆ’ x βˆ’ 12 x βˆ’ 12 = x3 βˆ’ 13 x βˆ’ 12Example 5 Expand these expressions and simplify if possible: a x(2x + 3)(x βˆ’ 7) b x(5x βˆ’ 3y)(2x βˆ’ y + 4) c (x βˆ’ 4)(x + 3)(x + 1) Be careful with minus signs. You need to change every sign in the second pair of brackets when you multiply it out. Choose one pair of brackets to expand first, for example: (x – 4)(x + 3) = x 2 + 3x – 4x – 12 = x2 – x – 12 You multiplied together three linear terms, so the final answer contains an x 3 term.–xy – xy = –2xy Multiply x by (3x βˆ’ 2y βˆ’ 4) and then multiply y by (3x βˆ’ 2y βˆ’ 4). Start by expanding one pair of brackets:x(2x + 3) = 2x 2 + 3x You could also have expanded the second pair of brackets first: (2x + 3)(x – 7) = 2x 2 – 11x – 21 Then multiply by x.(x βˆ’ y)2 means (x βˆ’ y) multiplied by itself. 1 Expand and simplify if possible: a (x + 4)(x + 7) b (x βˆ’ 3)(x + 2) c (x βˆ’ 2)2 d (x βˆ’ y)(2x + 3) e (x + 3y)(4x βˆ’ y) f (2x βˆ’ 4y)(3x + y) g (2x βˆ’ 3)(x βˆ’ 4) h (3x + 2y)2 i (2x + 8y)(2x + 3) j (x + 5)(2x + 3y βˆ’ 5) k (x βˆ’ 1)(3x βˆ’ 4y βˆ’ 5) l (x βˆ’ 4y)(2x + y + 5) m (x + 2y βˆ’ 1)(x + 3) n (2x + 2y + 3)(x + 6) o (4 βˆ’ y)(4y βˆ’ x + 3) p (4y + 5)(3x βˆ’ y + 2) q (5y βˆ’ 2x + 3)(x βˆ’ 4) r (4y βˆ’ x βˆ’ 2)(5 βˆ’ y)Exercise 1B
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6 Chapter 1 1.3 Factorising You can write expressions as a product of their factors. β–  Factorising is the opposite of expanding brack ets.4x(2x + y) (x + 5)3 (x + 2y)(x – 5y)= 8x2 + 4xy = x3 + 15x2 + 75x + 125 = x2 – 3xy – 10y2Expanding brackets FactorisingExpand and simplify ( x + y )4. You can use the binomial expansion to expand ex pressions like ( x + y )4 quickly. β†’ Section 8.3LinksChallenge2 Expand and simplify if possible: a 5(x + 1)(x βˆ’ 4) b 7(x βˆ’ 2)(2x + 5) c 3(x βˆ’ 3)(x βˆ’ 3) d x(x βˆ’ y)(x + y) e x(2x + y)(3x + 4) f y(x βˆ’ 5)(x + 1) g y(3x βˆ’ 2y)(4x + 2) h y(7 βˆ’ x)(2x βˆ’ 5) i x(2x + y)(5x βˆ’ 2) j x(x + 2)(x + 3y βˆ’ 4) k y(2x + y βˆ’ 1)(x + 5) l y(3x + 2y βˆ’ 3)(2x + 1) m x(2x + 3)(x + y βˆ’ 5) n 2x (3x βˆ’ 1)(4x βˆ’ y βˆ’ 3) o 3x (x βˆ’ 2y)(2x + 3y + 5) p (x + 3)(x + 2)(x + 1) q (x + 2)(x βˆ’ 4)(x + 3) r (x + 3)(x βˆ’ 1)(x βˆ’ 5) s (x βˆ’ 5)(x βˆ’ 4)(x βˆ’ 3) t (2x + 1)(x βˆ’ 2)(x + 1) u (2x + 3)(3x βˆ’ 1)(x + 2) v (3x βˆ’ 2)(2x + 1)(3x βˆ’ 2) w (x + y)(x βˆ’ y)(x βˆ’ 1) x (2x βˆ’ 3y)3 3 The diagram shows a rectangle with a square cut out. The rectangle has length 3 x βˆ’ y + 4 and width x + 7. The square has length x βˆ’ 2.Find an expanded and simplified expression for the shaded area. x – 2x + 7 3x – y + 4 4 A cuboid has dimensions x + 2 cm, 2x βˆ’ 1 cm and 2x + 3 cm. Show tha t the volume of the cuboid is 4x3 + 12x2 + 5x – 6 cm3. 5 Given tha t (2x + 5y)(3x βˆ’ y)(2x + y) = ax3 + bx2y + cxy2 + dy3, where a, b, c and d are constants, find the values of a, b, c and d. (2 marks)P Use the same strategy as you would use if the lengths were given as numbers: 3cm6cm 10cmProblem-solving P E/P
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7Algebraic expressions An ex pression in the form x2 – y2 is called the difference of two squares.Notation= (x + 3)(2x – 1)β–  A quadratic expression has the form ax2 + bx + c where a, b and c are real numbers and a β‰  0. To factorise a quadratic expression: β€’Find two fact ors of ac that add up to b β€’Rewrite the b term as a sum of these two factors β€’Factorise each p air of terms β€’Take out the c ommon factor β–  x2 βˆ’ y2 = (x + y)(x βˆ’ y)a 3x + 9 = 3( x + 3) b x2 βˆ’ 5 x = x(x βˆ’ 5) c 8x2 + 20 x = 4 x(2x + 5) d 9x2y + 15 xy2 = 3 xy(3x + 5 y) e 3x2 βˆ’ 9 xy = 3 x(x βˆ’ 3 y)Example 6 Factorise these expressions completely: a 3x + 9 b x2 βˆ’ 5 x c 8x2 + 20x d 9x2y + 15xy2 e 3x2 – 9xy 3 is a common factor of 3x and 9. For the expression 2x2 + 5x – 3, ac = –6 = –1 Γ— 6 and –1 + 6 = 5 = b. 2x2 – x + 6x – 3 = x(2x – 1) + 3(2x – 1)x is a common factor of x2 and –5x. 4 and x are common factors of 8x2 and 20x. So take 4x outside the brackets. 3, x and y are common factors of 9x2y and 15xy2. So take 3xy outside the brackets. x and –3y have no common factors so this expression is completely factorised. Real n umbers are all the positive and negative numbers, or zero, including fractions and surds.Notation Example 7 Factorise: a x2Β βˆ’Β 5xΒ βˆ’Β 6 b x2Β +Β 6xΒ +Β 8 c 6x2Β βˆ’Β 11xΒ βˆ’Β 10 d x2Β βˆ’Β 25 e 4x2Β βˆ’Β 9y2 a x2 βˆ’ 5 x βˆ’ 6 ac = βˆ’6 and b = βˆ’ 5 So x2 βˆ’ 5 x βˆ’ 6  x2 + x βˆ’ 6 x βˆ’ 6 = x(x + 1) βˆ’ 6( x + 1) = (x + 1)( x βˆ’ 6)Here aΒ =Β 1, bΒ =Β βˆ’ 5 and cΒ =Β βˆ’ 6. 1 Work out the two factors of ac =Β βˆ’ 6 which add t o give you bΒ =Β βˆ’5. βˆ’6 + 1Β =Β βˆ’5 2 Rewrite the b term using these two factors. 3 Factorise first two terms and last two terms. 4 xΒ + 1 is a factor of both terms, so take that outside the brackets. This is now completely factorised.
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8 Chapter 1 Example 8 Factorise completely: a x3 – 2x2 b x3 βˆ’ 25x c x3 + 3x2 βˆ’ 10xb x2 + 6 x + 8 = x2 + 2 x + 4 x + 8 = x(x + 2) + 4( x + 2) = (x + 2)( x + 4) c 6x2 βˆ’ 11 x βˆ’ 10 = 6x2 βˆ’ 15 x + 4 x βˆ’ 10 = 3x(2x βˆ’ 5) + 2(2 x βˆ’ 5) = (2 x βˆ’ 5)(3 x + 2) d x2 βˆ’ 25 = x2 βˆ’ 52 = (x + 5)( x βˆ’ 5) e 4x2 βˆ’ 9 y2 = 22x2 βˆ’ 32y2 = (2 x + 3y)(2x βˆ’ 3 y) a x3 – 2x2 = x2(x – 2) b x3 βˆ’ 25 x = x(x2 βˆ’ 25) = x(x2 βˆ’ 52) = x(x + 5)( x βˆ’ 5) c x3 + 3 x2 βˆ’ 10x = x (x2 + 3 x βˆ’ 10) = x(x + 5)( x βˆ’ 2) 1 Factorise these expressions completely:a 4x + 8 b 6x βˆ’ 24 c 20x + 15 d 2x2 + 4 e 4x2 + 20 f 6x2 βˆ’ 18x g x2 βˆ’ 7x h 2x2 + 4x i 3x2 βˆ’ x j 6x2 βˆ’ 2x k 10y2 βˆ’ 5y l 35x2 βˆ’ 28x m x2 + 2x n 3y2 + 2y o 4x2 + 12x p 5y2 βˆ’ 20y q 9xy2 + 12x2y r 6abΒ βˆ’ 2ab2 s 5x2 βˆ’ 25xy t 12x2y ξ€± 8xy2 u 15y βˆ’ 20yz2 v 12x2 βˆ’ 30 w xy2 βˆ’ x2y x 12y2 βˆ’ 4yxExercise 1Cx2 βˆ’ 25 is the difference of two squares.This is the difference of two squares as the two terms are x2 and 52. The two x terms, 5x and βˆ’ 5x, cancel each other out.acΒ =Β βˆ’60 and 4Β βˆ’Β 15Β =Β βˆ’11Β =Β b. Factorise. This is the same as (2x)2Β βˆ’Β (3y)2. You can’t factorise this any further. x is a common factor of x3 and βˆ’25x. So take x outside the brackets. Write the expression as a product of x and a quadratic factor. Factorise the quadratic to get three linear factors.acΒ =Β 8 and 2Β +Β 4Β =Β 6Β =Β b. Factorise.
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9Algebraic expressions Write 4x4 βˆ’ 13x2 + 9 as the product of four linear factors.Challenge2 Factorise: a x2 + 4x b 2x2 + 6x c x2 + 11x + 24 d x2 + 8x + 12 e x2 + 3xΒ βˆ’ 40 f x2 βˆ’ 8x + 12 g x2 + 5x + 6 h x2 βˆ’ 2xΒ βˆ’ 24 i x2 βˆ’ 3xΒ βˆ’ 10 j x2 +Β xΒ βˆ’ 20 k 2x2 + 5xΒ + 2 l 3x2 + 10x βˆ’ 8 m 5x2 βˆ’ 16xΒ + 3 n 6x2 βˆ’ 8x βˆ’ 8 o 2x2 + 7xΒ βˆ’ 15 p 2x4 + 14x2 + 24 q x2 βˆ’ 4 r x2 βˆ’ 49 s 4x2 βˆ’ 25 t 9x2 βˆ’ 25y2 u 36x2 βˆ’ 4 v 2x2 βˆ’ 50 w 6x2 βˆ’ 10xΒ + 4 x 15x2 + 42xΒ βˆ’ 9 3 Factorise completely:a x3 + 2x b x3 βˆ’ x2 + x c x3 βˆ’ 5x d x3 βˆ’ 9x e x3 βˆ’ x2 βˆ’ 12x f x3 + 11x2 + 30x g x3 βˆ’ 7x2 + 6x h x3 βˆ’ 64x i 2x3 βˆ’ 5x2 βˆ’ 3x j 2x3 + 13x2 + 15x k x3 βˆ’ 4x l 3x3 + 27x2 + 60x 4 Factorise completel y x4 βˆ’ y4. (2 marks) 5 Factorise completel y 6x3 + 7x2 βˆ’ 5x. (2 marks) For part n , ta ke 2 out as a common factor first. For part p , let yΒ =Β x2.Hint Watch out for terms that can be written as a function of a function: x4 = (x2)2Problem-solving P E 1.4 Negative and fractional indic es Indices can be negative numbers or fractions. x 1 _ 2 Γ— x 1 _ 2 = x 1 _ 2 + 1 _ 2 = x 1 = x, similarly x 1 __ n Γ— x 1 __ n Γ— . . . Γ— x 1 __ n = x 1 __ n + 1 __ n +...+ 1 __ n = x 1 = x n terms β–  You can use the laws of indices with any rational power. β€’ a 1 __ m = m βˆšβ€―__ a β€’ a n __ m = m βˆšβ€―___ a n β€’ a βˆ’m = 1 ___ a m β€’ a 0 = 1 ⎫ βŽͺβŽͺ⎬βŽͺβŽͺ⎭ Ratio nal numbers are those that can be written as a __ b where a and b are integers.Notation a 1 _ 2 = βˆšβ€―__ a is the positive square root of a . For example 9 1 _ 2 = βˆšβ€―__ 9 = 3 but 9 1 _ 2 β‰  βˆ’3 .Notation
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10 Chapter 1 Example 9 Simplify: a x 3 ___ x βˆ’3 b x1 2 Γ— x32 c (x3)23 d 2x1.5Β Γ·Β 4xβˆ’0.25 e 3 βˆšβ€―______ 125 x 6 f 2 x 2 βˆ’ x _______ x 5 a x 3 ____ x βˆ’3 = x3 βˆ’ (βˆ’3) = x6 b x1 2 Γ— x3 2 = x1 2 ξ€±Β 32 = x2 c (x3)23 =Β x3 ξ€³Β 23 =Β x2 d 2x1.5  4 x–0.25 = 1 __ 2 x1.5 – (–0 .25) = 1 __ 2 x1.75 e 3 √ _____ 125 x 6 = ( 125 x6 ) 1 __ 3 = (12 5 ) 1 __ 3 (x6 ) 1 __ 3 = 3 βˆšβ€―_____ 125 ( x 6 Γ— 1 __ 3 ) = 5 x2 f 2 x 2 βˆ’ x ______ x 5 = 2 x 2 ____ x 5 βˆ’ x ___ x 5 = 2 Γ— x2 βˆ’ 5 – x1 – 5 = 2x–3 – x–4 = 2 ___ x 3 βˆ’ 1 ___ x 4 Use the rule amΒ Γ·Β anΒ =Β am βˆ’ n. Evaluate: a 9 1 _ 2 b 6 4 1 _ 3 c 4 9 3 _ 2 d 2 5 βˆ’ 3 _ 2 Example 10 a 9 1 __ 2 = βˆšβ€―__ 9 = 3 b 6 4 1 __ 3 = 3 βˆšβ€―___ 64 = 4 c 4 9 3 __ 2 = ( βˆšβ€―___ 49 ) 3 73 = 343 d 2 5 – 3 __ 2 = 1 ____ 2 5 3 __ 2 = 1 ______ ( βˆšβ€―___ 25 ) 3 = 1 ___ 53 = 1 _____ 125 Using a 1 __ m = m βˆšβ€―__ a . 9 1 _ 2 = βˆšβ€―__ 9 Using a n __ m = m βˆšβ€―__ an . This means the square root o f 49, cubed. Using aβˆ’m = 1 ___ am This could also be written as βˆšβ€―__ x . Use the rule amΒ Γ—Β anΒ =Β am + n. Use the rule (am)nΒ =Β amn. Use the rule amΒ Γ·Β anΒ =Β am βˆ’ n. 1.5Β βˆ’Β (βˆ’0.25)Β =Β 1.75 Using a 1 __ m = m βˆšβ€―__ a . Divide each term of the numerator by x5. Using a βˆ’m = 1 ___ a m This means the cube root of 64. Use your calculator to enter ne gative and fractional powers.Online
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11Algebraic expressions 1 Simplify: a x3 Γ· xβˆ’2 b x5 Γ· x7 c x 3 _ 2 Γ— x 5 _ 2 d (x2 ) 3 _ 2 e (x3 ) 5 _ 3 f 3x0.5 Γ— 4xβˆ’0.5 g 9 x 2 _ 3 Γ· 3 x 1 _ 6 h 5 x 7 _ 5 Γ· x 2 _ 5 i 3x4 Γ— 2xβˆ’5 j βˆšβ€―__ x Γ— 3 βˆšβ€―__ x k ( βˆšβ€―__ x )3 Γ— ( 3 βˆšβ€―__ x )4 l ( 3 βˆšβ€―__ x )2 _____ βˆšβ€―__ x 2 Eva luate: a 2 5 1 _ 2 b 8 1 3 _ 2 c 2 7 1 _ 3 d 4βˆ’2 e 9 βˆ’ 1 _ 2 f (βˆ’ 5)βˆ’3 g ( 3 _ 4 ) 0 h 129 6 3 _ 4 i ( 25 __ 16 ) 3 2 j ( 27 __ 8 ) 2 3 k ( 6 _ 5 ) βˆ’1 l ( 343 ___ 512 ) βˆ’2 3 3 Simplify: a (64x10)1 2 b 5 x 3 βˆ’ 2 x 2 ________ x 5 c (125x12)1 3 d x + 4 x 3 _______ x 3 e 2x + x 2 _______ x 4 f ( 4 __ 9 x4) 3 2 g 9 x 2 βˆ’ 15 x 5 _________ 3 x 3 h 5x + 3 x 2 ________ 15 x 3 4 a Find the value of 8 1 1 _ 4 . (1 mark) b Simplify x(2 x βˆ’ 1 _ 3 )4. (2 marks) 5 Given tha t y = 1 __ 8 x 3 express each of the following in the form k x n , where k and n are constants. a y 1 3 (2 marks) b 1 __ 2 y βˆ’2 (2 marks)E EExercise 1Da y 1 _ 2 = ( 1 __ 16 x 2 ) 1 _ 2 = 1 ___ βˆšβ€―___ 16 x 2 Γ— 1 _ 2 = x __ 4 b 4y–1 = 4 ( 1 __ 16 x 2 ) βˆ’1 = 4 ( 1 __ 16 ) βˆ’1 x 2 Γ— (βˆ’1) = 4 Γ— 16 xβˆ’2 = 64 xβˆ’2Substitute y = 1 ___ 16 x 2 into y 1 _ 2 . ( 1 ___ 16 ) 1 _ 2 = 1 ____ √ ___ 16 and ( x 2 ) 1 _ 2 = x 2 Γ— 1 _ 2 Given that y = 1 __ 16 x2 express each of the following in the form k x n , where k and n are constants. a y 1 __ 2 b 4 y βˆ’1 Example 11 Check that your answers are in the correct form. If k and n are constants they could be positive or negative, and they could be integers, fractions or surds.Problem-solving ( 1 ___ 16 ) βˆ’1 = 16 and x2 Γ— βˆ’1 = xβˆ’2
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12 Chapter 1 1.5 Surds If n is an integer that is not a square number, then any multiple of βˆšβ€―__ n is called a surd. Examples of surds are βˆšβ€―__ 2 , βˆšβ€―___ 19 and 5 βˆšβ€―__ 2 . Surds are examples of irrational numbers. The decimal expansion of a surd is never-ending and never repeats, for example βˆšβ€―__ 2 = 1.414213562... You can use surds to write exact answers to calculations. β–  You can manipulate surds using these rules: β€’ βˆšβ€―___ ab = βˆšβ€―__ a Γ— βˆšβ€―__ b β€’ βˆšβ€―__ a __ b = βˆšβ€―__ a ___ βˆšβ€―__ b Irr ational numbers cannot be written in the form a __ b where a and b are integers. Surds are examples of irrational numbers .Notation Simplify: a βˆšβ€―___ 12 b βˆšβ€―___ 20 ____ 2 c 5 βˆšβ€―__ 6 βˆ’ 2 βˆšβ€―___ 24 + βˆšβ€―____ 294 Example 12 a βˆšβ€―___ 12 = βˆšβ€―_______ (4 Γ— 3) = βˆšβ€―__ 4 Γ— βˆšβ€―__ 3 = 2 βˆšβ€―__ 3 b βˆšβ€―___ 20 ____ 2 = βˆšβ€―__ 4 Γ— βˆšβ€―__ 5 ________ 2 = 2 Γ— βˆšβ€―__ 5 _______ 2 = βˆšβ€―__ 5 c 5 βˆšβ€―__ 6 βˆ’ 2 βˆšβ€―___ 24 + βˆšβ€―_____ 294 = 5 βˆšβ€―__ 6 βˆ’ 2 βˆšβ€―__ 6 βˆšβ€―__ 4 + βˆšβ€―__ 6 Γ— βˆšβ€―___ 49 = βˆšβ€―__ 6 (5 βˆ’ 2 βˆšβ€―__ 4 + βˆšβ€―___ 49 ) = βˆšβ€―__ 6 (5 βˆ’ 2 Γ— 2 + 7) = βˆšβ€―__ 6 (8) = 8 βˆšβ€―__ 6 βˆšβ€―__ 6 is a common factor. βˆšβ€―__ 4 = 2Look for a factor of 12 that is a square number. Use the rule βˆšβ€―___ ab = βˆšβ€―__ a Γ— βˆšβ€―__ b . βˆšβ€―__ 4 = 2 βˆšβ€―___ 20 = βˆšβ€―__ 4 Γ— βˆšβ€―__ 5 Cancel by 2. Work out the square roots βˆšβ€―__ 4 and βˆšβ€―___ 49 . 5 βˆ’ 4 + 7 = 8
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13Algebraic expressions Expand and simplify if possible: a βˆšβ€―__ 2 (5 βˆ’ βˆšβ€―__ 3 ) b (2 βˆ’ βˆšβ€―__ 3 )(5 + βˆšβ€―__ 3 ) Example 13 a βˆšβ€―__ 2 (5 βˆ’ βˆšβ€―__ 3 ) = 5 βˆšβ€―__ 2 βˆ’ βˆšβ€―__ 2 βˆšβ€―__ 3 = 5 βˆšβ€―__ 2 βˆ’ βˆšβ€―__ 6 b (2 βˆ’ βˆšβ€―__ 3 )(5 + βˆšβ€―__ 3 ) = 2(5 + βˆšβ€―__ 3 ) βˆ’ βˆšβ€―__ 3 (5 + βˆšβ€―__ 3 ) = 10 + 2 βˆšβ€―__ 3 βˆ’ 5 βˆšβ€―__ 3 βˆ’ βˆšβ€―__ 9 = 7 βˆ’ 3 βˆšβ€―__ 3 √ __ 2 Γ— 5 βˆ’ √ __ 2 Γ— √ __ 3 Using βˆšβ€―__ a Γ— √ __ b = √ ____ ab Collect like terms: 2 √ __ 3 βˆ’ 5 √ __ 3 = βˆ’3 √ __ 3 Simplify any roots if possible: √ __ 9 = 3 1 Do not use your calcula tor for this exercise. Simplify: a βˆšβ€―___ 28 b βˆšβ€―___ 72 c βˆšβ€―___ 50 d βˆšβ€―__ 32 e βˆšβ€―__ 90 f βˆšβ€―__ 12 ____ 2 g βˆšβ€―___ 27 ____ 3 h βˆšβ€―__ 20 + βˆšβ€―__ 80 i βˆšβ€―___ 200 + βˆšβ€―__ 18 βˆ’ βˆšβ€―__ 72 j βˆšβ€―___ 175 + βˆšβ€―__ 63 + 2 βˆšβ€―__ 28 k βˆšβ€―__ 28 βˆ’ 2 βˆšβ€―__ 63 + βˆšβ€―__ 7 l βˆšβ€―__ 80 βˆ’ 2 βˆšβ€―__ 20 + 3 βˆšβ€―__ 45 m 3 βˆšβ€―___ 80 βˆ’ 2 βˆšβ€―___ 20 + 5 βˆšβ€―___ 45 n βˆšβ€―___ 44 ____ βˆšβ€―___ 11 o βˆšβ€―___ 12 + 3 βˆšβ€―___ 48 + βˆšβ€―___ 75 2 Expand and simplify if possible: a √ __ 3 (2 + √ __ 3 ) b √ __ 5 (3 βˆ’ √ __ 3 ) c √ __ 2 (4 βˆ’ √ __ 5 ) d (2 βˆ’ √ __ 2 )(3 + √ __ 5 ) e (2 βˆ’ √ __ 3 )(3 βˆ’ √ __ 7 ) f (4 + √ __ 5 )(2 + √ __ 5 ) g (5 βˆ’ √ __ 3 )(1 βˆ’ √ __ 3 ) h (4 + √ __ 3 )(2 βˆ’ √ __ 3 ) i (7 βˆ’ √ ___ 11 )(2 + √ ___ 11 ) 3 Simplify √ ___ 75 βˆ’ √ ___ 12 giving your answer in the form a √ __ 3 , where a is an integer. (2 marks) EExercise 1E 1.6 Rationalising denominators If a fraction has a surd in the denominator, it is sometimes useful to rearrange it so that the denominator is a rational number. This is called rationalising the denominator. β–  The rules to rationalise denominators are: β€’For fractions in the f orm 1 ___ βˆšβ€―__ a , multiply the numerator and denominat or by βˆšβ€―__ a . β€’For fractions in the f orm 1 ______ a + βˆšβ€―__ b , multiply the numerator and denominat or by a βˆ’ βˆšβ€―__ b . β€’For fractions in the f orm 1 ______ a βˆ’ βˆšβ€―__ b , multiply the numerator and denominat or by a + βˆšβ€―__ b .Expand the brackets completely before you simplify.
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14 Chapter 1 Rationalise the denominator of: a 1 ___ βˆšβ€―__ 3 b 1 ______ 3 + βˆšβ€―__ 2 c βˆšβ€―__ 5 + βˆšβ€―__ 2 _______ βˆšβ€―__ 5 βˆ’ βˆšβ€―__ 2 d 1 ________ (1 βˆ’ βˆšβ€―__ 3 )2 Example 14 a 1 ___ βˆšβ€―__ 3 = 1 Γ— βˆšβ€―__ 3 ________ βˆšβ€―__ 3 Γ— βˆšβ€―__ 3 = βˆšβ€―__ 3 ___ 3 b 1 _______ 3 + βˆšβ€―__ 2 = 1 Γ— (3 βˆ’ βˆšβ€―__ 2 ) ________________ (3 + βˆšβ€―__ 2 )(3 βˆ’ βˆšβ€―__ 2 ) = 3 βˆ’ βˆšβ€―__ 2 ___________________ 9 βˆ’ 3 βˆšβ€―__ 2 + 3 βˆšβ€―__ 2 βˆ’ 2 = 3 βˆ’ βˆšβ€―__ 2 _______ 7 c βˆšβ€―__ 5 + βˆšβ€―__ 2 ________ βˆšβ€―__ 5 βˆ’ βˆšβ€―__ 2 = ( βˆšβ€―__ 5 + βˆšβ€―__ 2 )( βˆšβ€―__ 5 + βˆšβ€―__ 2 ) __________________ ( βˆšβ€―__ 5 βˆ’ βˆšβ€―__ 2 )( βˆšβ€―__ 5 + βˆšβ€―__ 2 ) = 5 + βˆšβ€―__ 5 βˆšβ€―__ 2 + βˆšβ€―__ 2 βˆšβ€―__ 5 + 2 _____________________ 5 βˆ’ 2 = 7 + 2 βˆšβ€―___ 10 __________ 3 d 1 _________ (1 βˆ’ βˆšβ€―__ 3 ) 2 = 1 ________________ (1 βˆ’ βˆšβ€―__ 3 )(1 βˆ’ βˆšβ€―__ 3 ) = 1 __________________ 1 βˆ’ βˆšβ€―__ 3 βˆ’ βˆšβ€―__ 3 + βˆšβ€―__ 9 = 1 ________ 4 βˆ’ 2 βˆšβ€―__ 3 = 1 Γ— (4 + 2 βˆšβ€―__ 3 ) __________________ (4 βˆ’ 2 βˆšβ€―__ 3 )(4 + 2 βˆšβ€―__ 3 ) = 4 + 2 βˆšβ€―__ 3 ______________________ 16 + 8 βˆšβ€―__ 3 βˆ’ 8 βˆšβ€―__ 3 βˆ’ 12 = 4 + 2 βˆšβ€―__ 3 ________ 4 = 2 + βˆšβ€―__ 3 _______ 2 Expand the brackets. √ __ 3 Γ— √ __ 3 = 3 βˆšβ€―__ 3 Γ— βˆšβ€―__ 3 = ( βˆšβ€―__ 3 )2 = 3Multiply the numerator and denominator by βˆšβ€―__ 3 . Multiply numerator and denominator by (3 – βˆšβ€―__ 2 ) . βˆšβ€―__ 2 Γ— βˆšβ€―__ 2 = 2 9 βˆ’ 2 = 7, βˆ’3 βˆšβ€―__ 2 + 3 βˆšβ€―__ 2 = 0 βˆšβ€―__ 5 βˆšβ€―__ 2 = βˆšβ€―___ 10 Multiply numerator and denominator by βˆšβ€―__ 5 + βˆšβ€―__ 2 . βˆ’ βˆšβ€―__ 2 βˆšβ€―__ 5 and βˆšβ€―__ 5 βˆšβ€―__ 2 cancel each other out. Simplify and collect like terms. √ __ 9 = 3 Multiply the numerator and denominator by 4 + 2 √ __ 3 . 16 βˆ’ 12 = 4, 8 √ __ 3 βˆ’ 8 √ __ 3 = 0
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15Algebraic expressions 1 Simplify: a 1 ___ βˆšβ€―__ 5 b 1 ____ βˆšβ€―___ 11 c 1 ___ βˆšβ€―__ 2 d βˆšβ€―__ 3 ____ βˆšβ€―___ 15 e βˆšβ€―__ 12 ____ βˆšβ€―__ 48 f βˆšβ€―__ 5 ____ βˆšβ€―___ 80 g βˆšβ€―___ 12 _____ βˆšβ€―____ 156 h βˆšβ€―__ 7 ____ βˆšβ€―___ 63 2 Rationa lise the denominators and simplify: a 1 ______ 1 + βˆšβ€―__ 3 b 1 ______ 2 + βˆšβ€―__ 5 c 1 ______ 3 βˆ’ βˆšβ€―__ 7 d 4 ______ 3 βˆ’ βˆšβ€―__ 5 e 1 _______ βˆšβ€―__ 5 βˆ’ βˆšβ€―__ 3 f 3 βˆ’ βˆšβ€―__ 2 ______ 4 βˆ’ βˆšβ€―__ 5 g 5 ______ 2 + βˆšβ€―__ 5 h 5 βˆšβ€―__ 2 _______ βˆšβ€―__ 8 βˆ’ βˆšβ€―__ 7 i 11 _______ 3 + βˆšβ€―___ 11 j βˆšβ€―__ 3 βˆ’ βˆšβ€―__ 7 _______ βˆšβ€―__ 3 + βˆšβ€―__ 7 k βˆšβ€―___ 17 βˆ’ βˆšβ€―___ 11 _________ βˆšβ€―___ 17 + βˆšβ€―___ 11 l βˆšβ€―___ 41 + βˆšβ€―___ 29 _________ βˆšβ€―___ 41 βˆ’ βˆšβ€―___ 29 m βˆšβ€―__ 2 βˆ’ βˆšβ€―__ 3 _______ βˆšβ€―__ 3 βˆ’ βˆšβ€―__ 2 3 Rationa lise the denominators and simplify: a 1 ________ (3 βˆ’ βˆšβ€―__ 2 ) 2 b 1 ________ (2 + βˆšβ€―__ 5 ) 2 c 4 ________ (3 βˆ’ βˆšβ€―__ 2 ) 2 d 3 ________ (5 + βˆšβ€―__ 2 ) 2 e 1 ______________ (5 + √ __ 2 )(3 βˆ’ √ __ 2 ) f 2 ______________ (5 βˆ’ √ __ 3 )(2 + √ __ 3 ) 4 Simplify 3 βˆ’ 2 βˆšβ€―__ 5 _______ βˆšβ€―__ 5 βˆ’ 1 giving your answer in the form p + q βˆšβ€―__ 5 , where p and q are rational numbers. (4 marks)E/P You can check that your answer is in the correct form by writing down the values of p and q and checking that they are rational numbers.Problem-solving 1 Simplify: a y3 Γ— y5 b 3x2 Γ— 2x5 c (4x2)3 Γ· 2x5 d 4b2 Γ— 3b3 Γ— b4 2 Expand and simplify if possible:a (x + 3)(x βˆ’ 5) b (2x βˆ’ 7)(3x + 1) c (2x + 5)(3x βˆ’ y + 2) 3 Expand and simplify if possible:a x(x + 4)(x βˆ’ 1) b (x + 2)(x βˆ’ 3)(x + 7) c (2x + 3)(x βˆ’ 2)(3x βˆ’ 1) 4 Expand the brackets:a 3(5y + 4) b 5x2(3 βˆ’ 5x + 2x2) c 5x(2 x + 3) βˆ’ 2x(1 βˆ’ 3x) d 3x2(1 + 3x) βˆ’ 2x(3x βˆ’2)Exercise 1F Mixed exercise 1
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16 Chapter 1 5 Factorise these expr essions completely: a 3x2 + 4x b 4y2 + 10y c x2 + xy + xy2 d 8xy2 + 10x2y 6 Factorise: a x2 + 3x + 2 b 3x2 + 6x c x2 βˆ’ 2x βˆ’ 35 d 2x2 βˆ’ x βˆ’ 3 e 5x2 βˆ’ 13x βˆ’ 6 f 6 βˆ’ 5 x βˆ’ x2 7 Factorise: a 2x3 + 6x b x3 βˆ’ 36x c 2x3 + 7x2 βˆ’ 15x 8 Simplify: a 9x3 Γ· 3xβˆ’3 b ( 4 3 _ 2 ) 1 _ 3 c 3xβˆ’2 Γ— 2x4 d 3 x 1 _ 3 Γ· 6 x 2 _ 3 9 Eva luate: a ( 8 ___ 27 ) 2 _ 3 b ( 225 ____ 289 ) 3 _ 2 10 Simplify: a 3 ____ βˆšβ€―___ 63 b βˆšβ€―__ 20 + 2 βˆšβ€―__ 45 βˆ’ βˆšβ€―__ 80 11 a Find the value of 35x2 + 2x βˆ’ 48 when x = 25. b By factorising the expression, sho w that your answer to part a can be written as the product of two prime factors. 12 Expand and simplify if possible: a βˆšβ€―__ 2 (3 + βˆšβ€―__ 5 ) b (2 βˆ’ βˆšβ€―__ 5 )(5 + βˆšβ€―__ 3 ) c (6 βˆ’ βˆšβ€―__ 2 )(4 βˆ’ βˆšβ€―__ 7 ) 13 Rationa lise the denominator and simplify: a 1 ____ βˆšβ€―___ 3 b 1 ______ βˆšβ€―__ 2 βˆ’ 1 c 3 ______ βˆšβ€―__ 3 βˆ’ 2 d βˆšβ€―___ 23 βˆ’ βˆšβ€―___ 37 _________ βˆšβ€―___ 23 + βˆšβ€―___ 37 e 1 ________ (2 + βˆšβ€―__ 3 )2 f 1 ________ (4 βˆ’ βˆšβ€―__ 7 )2 14 a Given tha t x3 βˆ’ x2 βˆ’ 17x βˆ’ 15 = (x + 3)(x2 + bx + c), where b and c are constants, work out the values of b and c. b Hence, fully factorise x3 βˆ’ x2 βˆ’ 17x βˆ’ 15. 15 Given tha t y = 1 __ 64 x 3 express each of the following in the form k x n , where k and n are constants. a y 1 _ 3 (1 mark) b 4 y βˆ’1 (1 mark) 16 Show that 5 _________ βˆšβ€―___ 75 βˆ’ βˆšβ€―___ 50 can be written in the form βˆšβ€―__ a + βˆšβ€―__ b , where a and b are integers. (5 marks) 17 Expand and simplify ( βˆšβ€―___ 11 βˆ’ 5)(5 βˆ’ βˆšβ€―___ 11 ) . (2 marks) 18 Factorise completel y x βˆ’ 64 x 3 . (3 marks) 19 Express 27 2x + 1 in the form 3 y , stating y in terms of x. (2 marks)E E/P E E E/P
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17Algebraic expressions 20 Solve the equation 8 + x βˆšβ€―___ 12 = 8x ___ βˆšβ€―__ 3 Give y our answer in the form a βˆšβ€―__ b where a and b are integers. (4 marks) 21 A rectangle has a length of (1 + βˆšβ€―__ 3 ) cm and area of βˆšβ€―___ 12 cm2. Calculate the width of the rectangle in cm. Express your answer in the form a + b βˆšβ€―__ 3 , where a and b are integers to be found. 22 Show that (2 βˆ’ βˆšβ€―__ x ) 2 ________ βˆšβ€―__ x can be written as 4 x βˆ’ 1 _ 2 βˆ’ 4 + x 1 _ 2 . (2 marks) 23 Given tha t 243 βˆšβ€―__ 3 = 3 a , find the value of a. (3 marks) 24 Given tha t 4 x 3 + x 5 _ 2 ________ βˆšβ€―__ x can be written in the form 4 x a + x b , write down the value of a and the value of b. (2 marks)E/P P E E/P E/P 1 You can use the laws of indices to simplify powers of the same base. ● am Γ— an = am + n ● am Γ· an = am βˆ’ n ● (am)n = amn ● (ab )n = anbn 2 Factorising is the opposite of expanding brackets. 3 A quadratic expr ession has the form ax2 + bx + c where a, b and c are real numbers and a β‰  0. 4 x2 βˆ’ y2 = (x + y)(x βˆ’ y) 5 You can use the law s of indices with any rational power. ● a 1 __ m = m βˆšβ€―__ a ● a n __ m = m βˆšβ€―__ a n ● a βˆ’m = 1 ___ a m ● a 0 = 1 6 You can manipulate sur ds using these rules: ● βˆšβ€―____ ab = βˆšβ€―__ a Γ— βˆšβ€―__ b ● βˆšβ€―__ a __ b = βˆšβ€―__ a ___ βˆšβ€―__ b 7 The rules to r ationalise denominators are: ● Fractions in the f orm 1 ___ βˆšβ€―__ a , multiply the numerator and denominat or by βˆšβ€―__ a . ● Fractions in the f orm 1 ______ a + βˆšβ€―__ b , multiply the numerator and denominat or by a βˆ’ βˆšβ€―__ b . ● Fractions in the f orm 1 ______ a βˆ’ βˆšβ€―__ b , multiply the numerator and denominat or by a + βˆšβ€―__ b .Summary of key pointsa Simplify ( βˆšβ€―__ a + βˆšβ€―__ b ) ( βˆšβ€―__ a βˆ’ βˆšβ€―__ b ) . b Hence show that 1 _______ βˆšβ€―__ 1 + βˆšβ€―__ 2 + 1 _______ βˆšβ€―__ 2 + βˆšβ€―__ 3 + 1 _______ βˆšβ€―__ 3 + βˆšβ€―__ 4 + ... + 1 _________ βˆšβ€―___ 24 + βˆšβ€―___ 25 = 4Challenge
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18 Quadratics After completing this chapter you should be able to: ● Solve quadratic equations using fact orisation, the quadratic formula and completing the square β†’ pages 19 βˆ’ 24 ● Read and use f(x) notation when working with functions β†’ pages 25 βˆ’ 27 ● Sketch the graph and find the turning point of a quadratic function β†’ pages 27 βˆ’ 30 ● Find and interpret the discriminant o f a quadratic expression β†’ pages 30 βˆ’ 32 ● Use and apply models that involv e quadratic functions β†’ pages 32 βˆ’ 35Objectives 1 Solve the following equations: a 3x + 6 = x βˆ’ 4 b 5(x + 3) = 6(2x βˆ’ 1) c 4x2 = 100 d (x βˆ’ 8)2 = 64 ← GCSE Mathematics 2 Factorise the following expressions: a x2 + 8x + 15 b x2 + 3x βˆ’ 10 c 3x2 βˆ’ 14x βˆ’ 5 d x2 βˆ’ 400 ← Section 1.3 3 Sketch the graphs of the following equations, labelling the points wher e each graph crosses the axes: a y = 3x βˆ’ 6 b y = 10 βˆ’ 2x c x + 2y = 18 d y = x2 ← GCSE Mathematics 4 Solve the following inequalities: a x + 8 , 11 b 2x βˆ’ 5 > 13 c 4x βˆ’ 7 < 2 (x βˆ’ 1) d 4 βˆ’ x , 11 ← GCSE MathematicsPrior knowledge check Quadratic functions are used to model projectile motion. Whenever an object is thrown or launched, its path will approximately follow the shape of a parabola. β†’ Mixed exercise Q112
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19Quadratics 2.1 Solving quadratic equations A quadratic equation can be written in the form ax2 + bx + c = 0, where a, b and c are real constants, and a β‰  0. Quadratic equations can have one, two, or no real solutions. β–  To solve a quadratic equation by factorising: β€’ Writ e the equation in the form ax2 + bx + c = 0 β€’ Factorise the left-hand side β€’ Set each factor equal to zero and solve to find the value(s) of x Example 1 The s olutions to an equation are sometimes called the roots of the equation.Notation The symbol β‡’ means β€˜implies that’ . This statement says β€˜If x + 3 = 0, then x = βˆ’3’.Notation a x2 βˆ’ 2x βˆ’ 15 = 0 (x + 3)( x βˆ’ 5) = 0 The n either x + 3 = 0 β‡’ x = βˆ’ 3 or x βˆ’ 5 = 0 β‡’ x = 5 So x = βˆ’ 3 and x = 5 are the two solutions of the equation. b x2 = 9x x2 βˆ’ 9 x = 0 x(x βˆ’ 9) = 0 Th en either x = 0 or x βˆ’ 9 = 0 β‡’ x = 9 The solutions are x = 0 and x = 9. c 6x2 + 13 x βˆ’ 5 = 0 (3x βˆ’ 1)(2x + 5) = 0 The n either 3 x βˆ’ 1 = 0 β‡’ x = 1 __ 3 or 2x + 5 = 0 β‡’ x = βˆ’ 5 __ 2 The s olutions are x = 1 __ 3 and x = βˆ’ 5 __ 2 d x2 βˆ’ 5 x + 18 = 2 + 3 x x2 βˆ’ 8 x + 16 = 0 (x βˆ’ 4)(x βˆ’ 4) = 0 Th en either x βˆ’ 4 = 0 β‡’ x = 4 or x βˆ’ 4 = 0 β‡’ x = 4 β‡’ x = 4Factorise. The s igns of the solutions are opposite to the signs of the constant terms in each factor.Watch outSolve the following equations: a x2 βˆ’ 2x βˆ’ 15 = 0 b x2 = 9x c 6x2 + 13x βˆ’ 5 = 0 d x2 βˆ’ 5x + 18 = 2 + 3xIf the product of the factors is zero, one of the factors must be zero.Factorise the quadratic. ← Section 1.3 A quadratic equation with two distinct factors has two distinct solutions. Be careful not to divide both sides by x, since x may have the value 0. Instead, rearrange into the form ax 2 + bx + c = 0. Factorise. Solutions to quadratic equations do not have to be integers. The quadratic equation (px + q)(rx + s) = 0 will have solutions x = βˆ’ q __ p and x = βˆ’ s __ r . When a quadratic equation has e xactly one root it is called a repeated root. You can also say that the equation has two equal roots.NotationRearrange into the form ax2 + bx + c = 0. Factorise.
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20 Chapter 2 In some cases it may be more straightforward to solve a quadratic equation without factorising. Example 2 Solve the following equations a (2x βˆ’ 3)2 = 25 b (x βˆ’ 3)2 = 7 a (2x βˆ’ 3)2 = 25 2x βˆ’ 3 = Β±5 2x = 3 Β± 5 The n either 2x = 3 + 5 β‡’ x = 4 or 2x = 3 βˆ’ 5 β‡’ x = βˆ’ 1 The solutions are x = 4 and x = βˆ’ 1 b (x βˆ’ 3)2 = 7 x βˆ’ 3 = Β± βˆšβ€―__ 7 x = 3 Β± βˆšβ€―__ 7 The s olutions are x = 3 + βˆšβ€―__ 7 and x = 3 βˆ’ βˆšβ€―__ 7 The symbol Β± lets you write two statements in one line of working. You say β€˜plus or minus’.Notation Add 3 to both sides. 1 Solve the following equations using factorisation: a x2 + 3x + 2 = 0 b x2 + 5x + 4 = 0 c x2 + 7x + 10 = 0 d x2 βˆ’ x βˆ’ 6 = 0 e x2 βˆ’ 8x + 15 = 0 f x2 βˆ’ 9x + 20 = 0 g x2 βˆ’ 5x βˆ’ 6 = 0 h x2 βˆ’ 4x βˆ’ 12 = 0 2 Solve the follo wing equations using factorisation: a x2 = 4x b x2 = 25x c 3x2 = 6x d 5x2 = 30x e 2x2 + 7x + 3 = 0 f 6x2 βˆ’ 7x βˆ’ 3 = 0 g 6x2 βˆ’ 5x βˆ’ 6 = 0 h 4x2 βˆ’ 16x + 15 = 0 3 Solve the follo wing equations: a 3x2 + 5x = 2 b (2x βˆ’ 3)2 = 9 c (x βˆ’ 7)2 = 36 d 2x2 = 8 e 3x2 = 5 f (x βˆ’ 3)2 = 13 g (3x βˆ’ 1)2 = 11 h 5x2 βˆ’ 10x2 = βˆ’7 + x + x2 i 6x2 βˆ’ 7 = 11x j 4x2 + 17x = 6x βˆ’ 2x2 4 This shape has an area of 44 m2. Find the value of x. 5 Solve the equation 5 x + 3 = βˆšβ€―______ 3x + 7 .2x mx m x m(x + 3) mP PExercise 2A Divide the shape into two sections:Problem-solvingTake the square root of both sides. Remember 52 = (βˆ’5)2 = 25. Take square roots of both sides. You can leave your answer in surd form.
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21Quadratics x = βˆ’ (βˆ’7) Β± √ ______________ (βˆ’7) 2 βˆ’ 4 (3) (βˆ’1) _______________________ 2 Γ— 3 x = 7 Β± √ _______ 49 + 12 _______________ 6 x = Β 7 Β± √ ___ 61 ________ 6 Β  The n x = 7 + √ ___ 61 ________ 6 or x = 7 βˆ’ √ ___ 61 _______ 6 Or x = 2.47 (3 s.f.) or x = βˆ’ 0.135 (3 s.f.)Example 3 Solve 3x2 βˆ’ 7x βˆ’1 = 0 by using the formula. βˆ’4 Γ— 3 Γ— (βˆ’1) = +12a = 3, b = βˆ’7 and c = βˆ’1. Put brackets around any negative values.Some equations cannot be easily factorised. You can also solve quadratic equations using the quadratic formula. β–  The solutions of the equation ax2 + bx + c = 0 are given by the formula: x = βˆ’b Β± βˆšβ€―________ b2 βˆ’ 4ac _____________ 2a You n eed to rearrange the equation into the form ax2 + bx + c = 0 before reading off the coefficients.Watch out 1 Solve the follo wing equations using the quadratic formula. Give your answers exactly, leaving them in surd form where necessary. a x2 + 3x + 1 = 0 b x2 βˆ’ 3x βˆ’ 2 = 0 c x2 + 6x + 6 = 0 d x2 βˆ’ 5x βˆ’ 2 = 0 e 3x2 + 10x βˆ’ 2 = 0 f 4x2 βˆ’ 4x βˆ’ 1 = 0 g 4x2 βˆ’ 7x = 2 h 11x2 + 2x βˆ’ 7 = 0 2 Solve the follo wing equations using the quadratic formula. Give your answers to three significant figures.a x2 + 4x + 2 = 0 b x2 βˆ’ 8x + 1 = 0 c x2 + 11x βˆ’ 9 = 0 d x2 βˆ’ 7x βˆ’ 17 = 0 e 5x2 + 9x βˆ’ 1 = 0 f 2x2 βˆ’ 3x βˆ’ 18 = 0 g 3x2 + 8 = 16x h 2x2 + 11x = 5x2 βˆ’ 18 3 For each of the equa tions below, choose a suitable method and find all of the solutions. Where necessary, give your answers to three significant figures.a x2 + 8x + 12 = 0 b x2 + 9x βˆ’ 11 = 0 c x2 βˆ’ 9x βˆ’ 1 = 0 d 2x2 + 5x + 2 = 0 e (2x + 8)2 = 100 f 6x2 + 6 = 12x g 2x2 βˆ’ 11 = 7x h x = Β  βˆšβ€―_______ 8x βˆ’ 15 You can use any method yo u are confident with to solve these equations.HintExercise 2B
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22 Chapter 2 Given that x is positive, solve the equation 1 __ x + 1 _____ x + 2 = 28 ____ 195 Challenge Write the equation in the form ax2 + bx + c = 0 before using the quadratic formula or factorising.Hint 2.2 Completing the square It is frequently useful to rewrite quadratic expressions by completing the square: β–  x2 + bx = (x + b __ 2 ) 2 βˆ’ ( b __ 2 ) 2 You can draw a diagram of this process when x and b are positive: The original rectangle has been rearranged into the shape of a square with a smaller square missing. The two areas shaded blue are the same.b 2 x xx x = b 2b x2 + bx = (x + b __ 2 ) 2 βˆ’ ( b __ 2 ) 2 a x2 + 8 x = ( x + 4)2 βˆ’ 42 = (x + 4)2 βˆ’ 16 b x2 βˆ’ 3 x = (x βˆ’ 3 _ 2 ) 2 βˆ’ ( 3 _ 2 ) 2 = (x βˆ’ 3 _ 2 ) 2 βˆ’ 9 _ 4 c 2x2 βˆ’ 12 x = 2( x2 βˆ’ 6 x) = 2(( x βˆ’ 3)2 βˆ’ 32) = 2(( x βˆ’ 3)2 βˆ’ 9) = 2(x βˆ’ 3)2 βˆ’ 18Example 4 Complete the square for the expressions: a x2 + 8x b x2 βˆ’ 3x c 2x2 + 12x A quadratic expression in the form p(x + q)2 + r where p, q and r are real constants is in completed square form.Notation Begin by halving the coefficient of x. Using the rule given above, b = 8 so b __ 2 = 4. Expand the outer bracket by multiplying 2 by 9 to get your answer in this form.4 This trapezium has an area of 50 m2. Show that the height of the trapezium is equal to 5( βˆšβ€―__ 5 βˆ’ 1) m. (x + 10) mx m 2x m Height must be positive. You will have to discard the negative solution of your quadratic equation.Problem-solvingP Be careful if b __ 2 is a fraction. Here ( 3 __ 2 ) 2 = 3 2 __ 2 2 = 9 __ 4 . Here the coefficient of x2 is 2, so take out a factor of 2. The other factor is in the form (x2 + bx) so you can use the rule to complete the square.
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23Quadratics 3x2 + 6 x + 1 = 3(x2 + 2x) + 1 = 3(( x + 1)2 βˆ’ 12) + 1 = 3(x + 1)2 βˆ’ 3 + 1 = 3(x + 1)2 βˆ’ 2 So p = 3, q = 1 and r = βˆ’ 2.Example 5 Write 3x2 + 6x + 1 in the form p(x + q)2 + r, where p, q and r are integers to be found. 1 Complete the square for the e xpressions: a x2 + 4x b x2 βˆ’ 6x c x2 βˆ’ 16x d x2 + x e x2 βˆ’ 14 2 Complete the square for the e xpressions: a 2x2 + 16x b 3x2 βˆ’ 24x c 5x2 + 20x d 2x2 βˆ’ 5x e 8x βˆ’ 2x2 3 Write each of these expressions in the form p(x + q)2 + r, where p, q and r are constants to be found: a 2x2 + 8x + 1 b 5x2 βˆ’ 15x + 3 c 3x2 + 2x βˆ’ 1 d 10 βˆ’ 16 x βˆ’ 4x2 e 2x βˆ’ 8x2 + 10 4 Given tha t x2 + 3x + 6 = (x + a)2 + b, find the values of the constants a and b. (2 marks) 5 Write 2 + 0.8x βˆ’ 0.04x2 in the form A βˆ’ B(x + C)2, where A, B and C are constants to beΒ determined. (3 marks)E EExercise 2C Solve the equation x2 + 8x + 10 = 0 by completing the square. Give your answers in surd form.Example 6 x2 + 8 x + 10 = 0 x2 + 8 x = βˆ’10 (x + 4)2 βˆ’ 42 = βˆ’10 (x + 4)2 = βˆ’10 + 16 (x + 4)2 = 6 (x + 4) = Β± βˆšβ€―__ 6 x = βˆ’4 Β± βˆšβ€―__ 6 So th e solutions are x = βˆ’4 + βˆšβ€―__ 6 and x = βˆ’ 4 βˆ’ βˆšβ€―__ 6 .Check coefficient of x2 = 1. Subtract 10 to get the LHS in the form x2 + bx. Complete the square for x2 + 8x. Add 42 to both sides. Take square roots of both sides. Subtract 4 from both sides. Leave your answer in surd form.β–  a x 2 + bx + c = a (x + b ___ 2a ) 2 + (c βˆ’ b 2 ____ 4 a 2 ) You could also use the rule given above to complete the square for this expression, but it is safer to learn the method shown here. This is an expression , so you can’t divide every term by 3 without changing its value. Instead, you need to take a factor of 3 out of 3x 2 + 6x .Watch out In question 3d , wr ite the expression as βˆ’4x2 βˆ’ 16 x + 10 then take a factor of βˆ’ 4 out of the first two terms to get βˆ’ 4(x 2 + 4x) + 10.Hint
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24 Chapter 2 Solve the equation 2x2 βˆ’ 8x + 7 = 0. Give your answers in surd form.Example 7 2x2 βˆ’ 8 x + 7 = 0 x2 βˆ’ 4 x + 7 __ 2 = 0 x2 βˆ’ 4 x = βˆ’ 7 __ 2 (x βˆ’ 2)2 βˆ’ 22 = βˆ’ 7 __ 2 (x βˆ’ 2)2 = βˆ’ 7 __ 2 + 4 (x βˆ’ 2)2 = 1 __ 2 x βˆ’ 2 = Β± βˆšβ€―__ 1 __ 2 x = 2 Β± 1 ___ βˆšβ€―__ 2 So th e roots are x = 2 + 1 ___ βˆšβ€―__ 2 and x = 2 βˆ’ 1 ___ βˆšβ€―__ 2 Complete the square for x2 βˆ’ 4x. Add 22 to both sides. Take square roots of both sides. Add 2 to both sides. 1 Solve these quadratic equations by completing the square. Leave your answers in surd form. a x2 + 6x + 1 = 0 b x2 + 12x + 3 = 0 c x2 + 4x βˆ’ 2 = 0 d x2 βˆ’ 10x = 5 2 Solve these quadra tic equations by completing the square. Leave your answers in surd form. a 2x2 + 6x βˆ’ 3 = 0 b 5x2 + 8x βˆ’ 2 = 0 c 4x2 βˆ’ x βˆ’ 8 = 0 d 15 βˆ’ 6 x βˆ’ 2x2 = 0 3 x2 βˆ’ 14x + 1 = (x + p)2 + q, where p and q are constants. a Find the values of p and q. (2 marks) b Using your answ er to part a, or otherwise, show that the solutions to the equation x2 βˆ’ 14x + 1 = 0 can be written in the form r Β± s βˆšβ€―__ 3 , where r and s are constants to be found. (2 marks) 4 By completing the square, sho w that the solutions to the equation x2 + 2bx + c = 0 are given by the formula x = βˆ’ b Β± βˆšβ€―______ b 2 βˆ’ c . (4 marks)E E/P Follow the same steps as you would if the coefficients were numbers.Problem-solvingExercise 2D Start by dividing the whole equation by a .Hint You can use this methodΒ to prove the quadratic formula. β†’ Section 7.4Linksa Show that the solutions to the equation ax2 + 2bx + c = 0 are given by x = βˆ’ b __ a Β± βˆšβ€―______ b 2 βˆ’ ac ______ a 2 . b Hence, or otherwise, sho w that the solutions to the equation ax2 + bx + c = 0 can be written as x = βˆ’b Β± βˆšβ€―_______ b 2 βˆ’ 4ac ____________ 2a .Challenge Use your calculator to check so lutions to quadratic equations quickly.OnlineThis is an equation so you can divide every term by the same constant. Divide by 2 to get x2 on its own. The right-hand side is 0 so it is unchanged.Problem-solving
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25Quadratics 2.3 Functions A function is a mathematical relationship that maps each value of a set of inputs to a single output. The notation f(x) is used to represent a function of x. β–  The set of possible inputs for a function is called the domain. 3DomainR ange 7 –7 2f(–7) = 49f(7) = 49f(3) = 9 f( 2) = 29 49 49 21 41 16 f( ) = 14 1 16β–  The set of possible outputs of a function is called the range. This diagram sho ws how the function f(x) = x2 maps five values in its domain to values in its range. β–  The roots of a function are the values of x for which f( x) = 0. The functions f and g are given by f(x) = 2x βˆ’ 10 If the i nput of a function, x, can be any real number the domain can be written as x ∈ ℝ . The s ymbol ∈ mean s β€˜is a member of’ and the symbol ℝ rep resents the real numbers.Notation and g(x) = x2 βˆ’ 9, x ∈ ℝ . a Find the values of f(5) and g(10). b Find the value of x for which f(x) = g(x).Example 8 a f(5) = 2(5) βˆ’ 10 = 10 βˆ’ 10 = 0 g (10) = (10)2 βˆ’ 9 = 100 βˆ’ 9 = 91 b f(x) = g(x) 2x βˆ’ 10 = x2 βˆ’ 9 x2 βˆ’ 2 x + 1 = 0 (x βˆ’ 1)2 = 0 x = 1To find f(5), substitute x = 5 into the function f(x). Set f(x) equal to g(x) and solve for x. The function f is defined as f(x) = x2 + 6x βˆ’ 5, Β x ∈ ℝ . a Write f(x ) in the form (x + p)2 + q. b Hence, or otherwise, find the r oots of f(x), leaving your answers in surd form. c Write down the minim um value of f(x), and state the value of x for which it occurs.Example 9 a f(x) = x2 + 6 x βˆ’ 5 = (x + 3)2 βˆ’ 9 βˆ’ 5 = (x + 3)2 βˆ’ 14 b f(x) = 0 (x + 3)2 βˆ’ 14 = 0 (x + 3)2 = 14 x + 3 = Β± βˆšβ€―____ 14 x = βˆ’3 Β± βˆšβ€―____ 14 f(x) has two roots: βˆ’3 + βˆšβ€―____ 14 and βˆ’ 3 βˆ’ βˆšβ€―____ 14 .Complete the square for x2 + 6x and then simplify the expression. You can solve this equation directly. Remember to write Β± when you take square roots of both sides.To find the root(s) of a function, set it equal to zero.
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26 Chapter 2 c (x + 3)2 > 0 So the minimum value of f( x) is βˆ’14. This occurs when ( x + 3)2 = 0, so when x = βˆ’ 3A squared value must be greater than or equal to 0. Find the roots of the function f(x) = x6 + 7x3 βˆ’ 8, x ∈ ℝ .Example 10 f(x) = 0 x6 + 7x3 βˆ’ 8 = 0 (x3)2 + 7( x3) βˆ’ 8 = 0 (x3 βˆ’ 1)( x3 + 8) = 0 So x3 = 1 or x3 = βˆ’8 x3 = 1 β‡’ x = 1 x3 = βˆ’8 β‡’ x = βˆ’ 2 The roots of f( x) are 1 and βˆ’ 2. Alternatively, let u = x3. f(x) = x6 + 7x3 βˆ’ 8 = (x3)2 + 7( x3) βˆ’ 8 = u2 + 7u βˆ’ 8 = (u βˆ’ 1)( u + 8) So when f( x) = 0, u = 1 or u = βˆ’ 8. If u = 1 β‡’ x3 = 1 β‡’ x = 1 If u = βˆ’ 8 β‡’ x3 = βˆ’8 β‡’ x = βˆ’ 2 The roots of f( x) are 1 and βˆ’ 2.Treat x3 as a single variable and factorise. Solve the quadratic equation to find two values for x3, then find the corresponding values of x. You can simplify this working with a substitution. Replace x3 with u and solve the quadratic equation in u. The s olutions to the quadratic equation will be values of u. Convert back to values of x using your substitution.Watch out 1 Using the functions f(x) = 5x + 3, g(x) = x2 βˆ’ 2 and h(x) = βˆšβ€―_____ x + 1 , find the values of: a f(1) b g(3) c h(8) d f(1.5) e g ( βˆšβ€―__ 2 ) f h (βˆ’1) g f(4) + g(2) h f(0) + g(0) + h(0) i g(4) ____ h(3) 2 The function f(x) is defined b y f(x) = x2 βˆ’ 2x, x ∈ ℝ . Giv en that f(a) = 8, find two possible values for a. 3 Find all of the r oots of the following functions: a f(x) = 10 βˆ’ 15x b g(x) = (x + 9)(x βˆ’ 2) c h(x) = x2 + 6x βˆ’ 40 d j(x) = 144 βˆ’ x2 e k(x) = x(x + 5)(x + 7) f m(x) = x3 + 5x2 βˆ’ 24xSubstitute x = a into the function and set the resulting expression equal to 8.Problem-solving PExercise 2Ef(x) can be written as a function of a function. The only powers of x in f( x) are 6, 3 and 0 so you can write it as a quadratic function of x3.Problem-solving(x + 3)2 > 0 so (x + 3)2 βˆ’ 14 > βˆ’14
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27Quadratics 4 The functions p and q are giv en by p(x) = x2 βˆ’ 3x and q(x) = 2x βˆ’ 6, x ∈ ℝ . Find the two v alues of x for which p(x) = q(x). 5 The functions f and g are gi ven by f(x) = 2x3 + 30x and g(x) = 17x2, Β x ∈ ℝ . Find the three v alues of x for which f(x) = g(x). 6 The function f is defined as f(x ) = x2 βˆ’ 2x + 2, x ∈ ℝ . a Write f(x ) in the form (x + p)2 + q, where p and q are constants to be found. (2 marks) b Hence, or otherwise, e xplain why f(x) > 0 for all values of x, and find the minimum value of f(x). (1 mark) 7 Find all roots of the following functions: a f(x) = x6 + 9x3 + 8 b g(x) = x4 βˆ’ 12x2 + 32 c h(x) = 27x6 + 26x3 βˆ’ 1 d j(x) = 32x10 βˆ’ 33x5 + 1 e k(x) = x βˆ’ 7 βˆšβ€―__ x + 10 f m(x) = 2 x 2 _ 3 + 2 x 1 _ 3 βˆ’ 12 8 The function f is defined as f(x ) = 32x βˆ’ 28(3x) + 27, x ∈ ℝ . a Write f(x ) in the form (3x βˆ’ a)(3x βˆ’ b), where a and b are real constants. (2 marks) b Hence find the two roots of f(x). (2 marks)E The function in par t b has four roots.Hint E/P Consider f( x) as a function of a function.Problem-solving 2.4 Quadratic graphs When f(x) = ax2 + bx + c, the graph of y = f(x) has a curved shape called a parabola. You can sketch a quadratic graph by identifying key features. The coefficient of x2 determines the overall shape of the graph. When a is positive the parabola will have this shape: When a is negative the parabola will have this shape: y x Oy x O1 The graph crosses the y-axis when x = 0. The y-coordinate is equal to c. 3 Quadratic graphs have one turning point. This can be a minimum or a maximum. Sinc eΒ a parabola is symmetrical, the turning point and line of symmetry are half-way between the two roots. 2 The graph crosses the x-axis when y = 0. The x-c oordinates are roots of the function f(x). 11 2 2 2 2 33 β–  You can find the coordinates of the turning point of a quadr atic graph by completing the square. If f(x) = a(x + p)2 + q, the graph of y = f(x) has a turning point at (βˆ’ p, q). The graph of y = a (x + p )2 + q is a translation of the graph of y = ax2 by ( βˆ’p q ) . β†’ Section 4.5Links
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28 Chapter 2 As a = 1 is positive, the graph has a shape and a minimum point. When x = 0, y = 4, so the graph crosses the y-axis at (0, 4). When y = 0, x2 βˆ’ 5 x + 4 = 0 (x βˆ’ 1)( x βˆ’ 4) = 0 x = 1 or x = 4, so the graph crosses the x-axis at (1, 0) and (4, 0). Completing the square: x 2 βˆ’ 5 x + 4 = (x βˆ’ 5 _ 2 ) 2 βˆ’ 25 __ 4 + 4 = (x βˆ’ 5 _ 2 ) 2 βˆ’ 9 _ 4 So th e minimum point has coordinates ( 5 _ 2 , βˆ’ 9 _ 4 ) . Alternatively, the minimum occurs when x is half-way between 1 and 4, so x = 1 + 4 _______ 2 = 5 _ 2 y = ( 5 _ 2 ) 2 βˆ’ 5 Γ— ( 5 _ 2 ) + 4 = βˆ’ 9 _ 4 so th e minimum has coordinates ( 5 _ 2 , βˆ’ 9 _ 4 ) . The sketch of the graph is: O xy /four.ss01 1 /four.ss01 , –5 294()Use the coefficient of x2 to determine the general shape of the graph. This example factorises, but you may need to use the quadratic formula or complete the square. Complete the square to find the coordinates of the turning point. You could use a graphic calculator or substitute some values to check your sketch. When x = 5, y = 5 2 βˆ’ 5 Γ— 5 + 4 = 4.Sketch the graph of y = x2 βˆ’ 5x + 4, and find the coordinates of its turning point.Example 11 If yo u use symmetry to find the x-coordinate of the minimum point, you need to substitute this value into the equation to find the y-coordinate of the minimum point.Watch out Explore how the graph of y = (x + p )2 + q changes as the values of p and q change using GeoGebra.Online
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29Quadratics As a = βˆ’ 2 is negative, the graph has a shape and a maximum point. When x = 0, y = βˆ’ 3, so the graph crosses the y -axis at (0, βˆ’ 3). When y = 0,βˆ’2x 2 + 4x βˆ’ 3 = 0 Using the quadratic formula, x = βˆ’4 Β± √ _____________ 4 2 βˆ’ 4 (βˆ’2) (βˆ’3) ____________________ 2 Γ— (βˆ’2) x = βˆ’4 Β± √ ____ βˆ’8 __________ βˆ’4 The re are no real solutions, so the graph does not cross the x -axis. Completing the square: βˆ’2x2 + 4x βˆ’ 3 = βˆ’2(x2 βˆ’ 2x) βˆ’ 3 = βˆ’2((x βˆ’ 1)2 βˆ’ 1) βˆ’ 3 = βˆ’2(x βˆ’ 1)2 + 2 βˆ’ 3 = βˆ’2(x βˆ’ 1)2 βˆ’ 1 So the maximum point has coordinates (1, βˆ’1). The line of symmetry is vertical and goes through the maximum point. It has the equation x = 1. O xy (1, –1) –3a = βˆ’2, b = 4 and c = βˆ’3Sketch the graph of y = 4x βˆ’ 2x2 βˆ’ 3. Find the coordinates of its turning point and write down the equation of its line of symmetry.Example 12 A ske tch graph does not need to be plotted exactly or drawn to scale. However you should:● dra w a smooth curve by hand ● ide ntify any relevant key points (such as intercepts and turning points) ● lab el your axes.Watch outIt’s easier to see that a , 0 if you write the equation in the form y = βˆ’2x 2 + 4x βˆ’ 3. You would need to square root a negative number to evaluate this expression. Therefore this equation has no real solutions. The coefficient of x2 is βˆ’2 so take out a factor of βˆ’ 2
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30 Chapter 2 1 Sketch the gra phs of the following equations. For each graph, show the coordinates of the point(s) where the graph crosses the coordinate axes, and write down the coordinate of the turning point and the equation of the line of symmetry. a y = x2 βˆ’ 6x + 8 b y = x2 + 2x βˆ’ 15 c y = 25 βˆ’ x2 d y = x2 + 3x + 2 e y = βˆ’x2 + 6x + 7 f y = 2x2 + 4x + 10 g y = 2x2 + 7x βˆ’ 15 h y = 6x2 βˆ’ 19x + 10 i y = 4 βˆ’ 7x βˆ’ 2x2 j y = 0.5x2 + 0.2x + 0.02 2 These sketches are gr aphs of quadratic functions of the form ax2 + bx + c. Find the values of a, b and c for each function. a y x15 5 3y = f(x) b y x10 –2 5y = g(x) c y x –183 –3 y = h(x) d y x –14–1 y = j(x) 3 The graph of y = ax2 + bx + c has a minimum at (5, βˆ’3) and passes through (4, 0). Find the values of a, b and c. (3 marks)P E/PExercise 2F 2.5 The discriminant If you square any real number, the result is greater than or equal to 0. This means that if y is negative, βˆšβ€―__ y cannot be a real number. Look at the quadratic formula: x = βˆ’b Β± βˆšβ€―_______ b 2 βˆ’ 4ac ____________ 2a β–  For the quadratic function f( x) = ax2 + bx + c, the expression b2 βˆ’ 4ac is called the discriminant. The value of the discriminant shows how many roots f( x) has: β€’If b2 βˆ’ 4ac . 0 then f( x) has two distinct real roots. β€’If b2 βˆ’ 4ac = 0 then f( x) has one repeated root. β€’If b2 βˆ’ 4ac , 0 then f( x) has no real roots.Check your answers by substituting values into the function. In part c the graph passes through (0, βˆ’ 18), so h(0) should be βˆ’ 18.Problem-solving If the value under the square root sign is negative, x cannot be a real number and there are no real solutions. If the value under the square root is equal to 0, both solutions will be the same.
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31Quadratics You can use the discriminant to check the shape of sketch graphs. Below are some graphs of y = f(x) where f(x) = ax2 + bx + c. a . 0 y x O y x O y x O b2 βˆ’ 4ac . 0 b2 βˆ’ 4ac = 0 b2 βˆ’ 4ac , 0 Two distinct real roots One repeated r oot No real roots a , 0 y x O y x O y x O Find the range of values of k for which x2 + 4x + k = 0 has two distinct real solutions.Example 14 x2 + 4x + k = 0 Here a = 1, b = 4 and c = k . For two real solutions, b2 βˆ’ 4 ac . 0 42 βˆ’ 4 Γ— 1 Γ— k . 0 16 βˆ’ 4 k . 0 16 . 4 k 4 . k So k , 4This statement involves an inequality, so your answer will also be an inequality.Find the values of k for which f(x) = x2 + kx + 9 has equal roots.Example 13 x2 + kx + 9 = 0 Here a = 1, b = k and c = 9 For equal roots, b2 βˆ’ 4 ac = 0 k2 βˆ’ 4 Γ— 1 Γ— 9 = 0 k2 βˆ’ 36 = 0 k2 = 36 so k = Β± 6Use the condition given in the question to write a statement about the discriminant.Problem-solving Substitute for a, b and c to get an equation with one unknown. Solve to find the values of k. For any value of k less than 4, the equation will have 2 distinct real solutions. Explore how the value of the di scriminant changes with k using GeoGebra.Online
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32 Chapter 2 1 a Calcula te the value of the discriminant for each of these five functions: i f(x) = x2 + 8x + 3 ii g(x) = 2x2 βˆ’ 3x + 4 iii h(x) = βˆ’x2 + 7x βˆ’ 3 iv j(x) = x2 βˆ’ 8x + 16 v k(x ) = 2x βˆ’ 3x2 βˆ’ 4 b Using your answ ers to part a, match the same five functions to these sketch graphs. i x Oy ii x Oy iii Oy iv x Oy v x Oy 2 Find the values of k for which x2 + 6x + k = 0 has two real solutions. (2 marks) 3 Find the value of t for which 2x2 βˆ’ 3x + t = 0 has exactly one solution. (2 marks) 4 Given tha t the function f(x ) = sx2 + 8x + s has equal roots, find the value of the positive constant s. (2 marks) 5 Find the range of v alues of k for which 3x2 βˆ’ 4x + k = 0 has no real solutions. (2 marks) 6 The function g(x) = x2 + 3px + (14p βˆ’ 3), where p is an integer, has two equal roots. a Find the value of p. (2 marks) b For this va lue of p, solve the equation x2 + 3px + (14p βˆ’ 3) = 0. (2 marks) 7 h(x) = 2x2 + (k + 4)x + k, where k is a real constant. a Find the discriminant of h(x ) in ter ms of k . (3 marks) b Hence or otherwise, pro ve that h(x ) has two distinct real roots for all values of k . (3 marks)E/P E/P E/P E/P E/P E/PExercise 2G 2.6 Modelling with quadratics A mathematical model is a mathematical description of a real-life situation. Mathematical models use the language and tools of mathematics to represent and explore real-life patterns and relationships, and to predict what is going to happen next. Models can be simple or complicated, and their results can be approximate or exact. Sometimes a model is only valid under certain circumstances, or for a limited range of inputs. You will learn more about how models involve simplifications and assumptions in Statistics and Mechanics. Quadratic functions can be used to model and explore a range of practical contexts, including projectile motion.a Prove that, if the values of a and c are given and non-zero, it is always possible to choose a value of b so that f(x) = ax2 + bx + c has distinct real roots. b Is it alway s possible to choose a value of b so that f(x) has equal roots? Explain your answer.ChallengeIf a question part says β€˜hence or otherwise’ it is usually easier to use your answer to the previous question part.Problem-solving
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33Quadratics A spear is thrown over level ground from the top of a tower. The height, in metres, of the spear above the ground after t seconds is modelled by the function: h(t) = 12.25 + 14.7t βˆ’ 4.9t2, t > 0 a Interpret the meaning of the constant ter m 12.25 in the model. b After how many seconds does the spear hit the gr ound? c Write h(t ) in the form A βˆ’ B(t βˆ’ C)2, where A, B and C are constants to be found. d Using your answ er to part c or otherwise, find the maximum height of the spear above the ground, and the time at which this maximum height is reached.Example 15 a The tower is 12.25 m tal l, since this is the height at time 0. b Whe n the spear hits the ground, the height is equal to 0. 12.25 + 14.7 t βˆ’ 4.9 t2 = 0 Using the formula, where a = βˆ’ 4.9, b = 14.7 and c = 12.25, t = βˆ’14.7 Β± √ ___________________ 14. 7 2 βˆ’ 4 (βˆ’4.9 ) (12.25 ) _______________________________ (2 Γ— βˆ’4.9) t = βˆ’14.7 Β± √ ______ 456.19 _________________ βˆ’9.8 t = Β βˆ’0.679 or t = 3.68 (to 3 s .f.) As t > 0, t = 3.68 seconds (to 3 s.f.). c 12. 25 + 14.7 t βˆ’ 4.9 t2 = βˆ’4.9(t2 βˆ’ 3 t) + 12.25 = βˆ’4.9(( t βˆ’ 1.5)2 βˆ’ 2.25) + 12.25 = βˆ’4.9(( t βˆ’ 1.5)2 + 11.025 + 12.25) = 23.275 βˆ’ 4.9( t βˆ’ 1.5)2 So A = 23.275, B = 4.9 and C = 1.5. d The m aximum height of the spear is 23.275 metres, 1.5 seconds after the spear is thrown.Give any non-exact numerical answers correct to 3 significant figures unless specified otherwise. Always interpret your answers in the context of the model. t is the time after the spear was thrown so it must be positive.Read the question carefully to work out the meaning of the constant term in the context of the model. Here, t = 0 is the time the spear is thrown.Problem-solving To solve a quadratic, factorise, use the quadratic formula, or complete the square. 4.9(t βˆ’ 1.5)2 must be positive or 0, so h(t ) < 23.275 for all possible values of t . The turning point of the graph of this function would be at (1.5, 23.275). You may find it helpful to draw a sketch of the function when working through modelling questions. Explore the trajectory of the sp ear using GeoGebra.Online
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34 Chapter 2 1 The diagram sho ws a section of a suspension bridge carrying a road over water. The height of the cables above water level in metres can be modelled by the function h(x)Β =Β 0.000 12x2 + 200, where x is the displacement in metres from the centre of the bridge. a Interpret the meaning of the constant ter m 200 in the model. (1 mark) b Use the model to find the two v alues of x at which the height is 346 m. (3 marks) c Given tha t the towers at each end are 346 m tall, use your ans wer to part b to calculate the length of the bridge to the nearest metre. (1 mark) 2 A car manufacturer uses a mode l to predict the fuel consumption, y miles per gallon (mpg), for a specific model of car travelling at a speed of x mph. y = βˆ’0.01x2 + 0.975x + 16, x . 0 a Use the model to find two speeds a t which the car has a fuel consumption of 32.5 mpg. (3 marks) b Rewrite y in the form A βˆ’ B(x βˆ’ C)2, where A, B and C are constants to be found. (3 marks) c Using your answ er to part b, find the speed at which the car has the greatest fuel efficiency. (1 mark) d Use the model to calcula te the fuel consumption of a car travelling at 120 mph. Comment on the va lidity of using this model for very high speeds. (2 marks) 3 A fertiliser company uses a model to deter mine how the amount of fertiliser used, fΒ kilograms per hectare, affects the grain yield g, measured in tonnes per hectare. g = 6 + 0.03f βˆ’ 0.000 06fΒ 2 a According to the model, how much grain would each hectare yield without any fertiliser? (1 mark) b One farmer currentl y uses 20 kilograms of fertiliser per hectare. How much more fertiliser would he need to use to increase his grain yield by 1 tonne per hectare? (4 marks) 4 A football stadium has 25 000 seats. The f ootball club know from past experience that they will sell only 10 000 tickets if each tick et costs Β£30. They also expect to sell 1000 more tickets every time the price goes down by Β£1. a The number of tick ets sold t can be modelled by the linear equation t = M βˆ’ 1000p, where Β£p is the price of each ticket and M is a constant. Find the value of M. (1 mark)E/P E/P E/P E/PExercise 2H For part a , make sure your answer is in the context of the model. Problem-solving
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35Quadratics The total revenue, Β£r, can be calculated by multiplying the number of tickets sold by the price of each ticket. This can be written as r = p(M βˆ’ 1000p). b Rearrange r into the f orm A βˆ’ B(p βˆ’ C)2, where A, B and C are constants to be found. (3 marks) c Using your answ er to part b or otherwise, work out how much the football club should charge for each ticket if they want to make the maximum amount of money. (2 marks) 1 Solve the follo wing equations without a calculator. Leave your answers in surd form whereΒ necessary. a y2 + 3y + 2 = 0 b 3x2 + 13x βˆ’ 10 = 0 c 5x2 βˆ’ 10x = 4x + 3 d (2x βˆ’ 5)2 = 7 2 Sketch gra phs of the following equations: a y = x2 + 5x + 4 b y = 2x2 + x βˆ’ 3 c y = 6 βˆ’ 10x βˆ’ 4x2 d y = 15x βˆ’ 2x2 3 f(x) = x2 + 3x βˆ’ 5 and g(x) = 4x + k, where k is a constant. a Given tha t f(3) = g(3), find the value of k. (3 marks) b Find the values of x for which f(x) = g(x). (3 marks) 4 Solve the follo wing equations, giving your answers correct to 3 significant figures: a k2 + 11k βˆ’ 1 = 0 b 2t2 βˆ’ 5t + 1 = 0 c 10 βˆ’ x βˆ’ x2 = 7 d (3x βˆ’ 1)2 = 3 βˆ’ x2 5 Write each of these expressions in the form p (x + q)2 + r, where p , q and r are constants to beΒ found: a x2 + 12x βˆ’ 9 b 5x2 βˆ’ 40x + 13 c 8x βˆ’ 2x2 d 3x2 βˆ’ (x + 1)2 6 Find the value k for which the equation 5x2 βˆ’ 2x + k = 0 has exactly one solution. (2 marks)E EMixed exercise 2Accident investigators are studying the stopping distance of a particular car. When the car is travelling at 20 mph, its stopping distance is 6 f eet. When the car is travelling at 30 mph, its stopping distance is 14 f eet. When the car is travelling at 40 mph, its stopping distance is 24 f eet. The investigators suggest that the stopping distance in feet, d, is a quadratic function of the speed in miles per hour, s. a Given that d(s ) = as2 + bs + c, find the values of the constants a, b and c. b At an accident sc ene a car has left behind a skid that is 20 feet long. Use your model to calculate the speed that this car was going at before the accident.Challenge Start by setting up three si multaneous equations. Combine two different pairs of equations to eliminate c . Use the results to find the values of a and b first.Hint
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36 Chapter 2 7 Given tha t for all values of x: 3x2 + 12x + 5 = p(x + q)2 + r a find the values of p, q and r. (3 marks) b Hence solve the equation 3 x2 + 12x + 5 = 0. (2 marks) 8 The function f is defined as f(x ) = 22x βˆ’ 20(2x) + 64, x ∈ ℝ . a Write f(x ) in the form (2x βˆ’ a)(2x βˆ’ b), where a and b are real constants. (2 marks) b Hence find the two roots of f(x). (2 marks) 9 Find, as surds, the r oots of the equation: 2(x + 1)(x βˆ’ 4) βˆ’ (x βˆ’ 2)2 = 0. 10 Use algebr a to solve (x βˆ’ 1)(x + 2) = 18. 11 A diver launches herse lf off a springboard. The height of the diver, in metres, above the pool tΒ seconds after launch can be modelled by the following function: h(t) = 5t βˆ’ 10t2 + 10, t > 0 a How high is the springboard a bove the water? (1 mark) b Use the model to find the time at w hich the diver hits the water. (3 marks) c Rearrange h( t) into the form A βˆ’ B(t βˆ’ C)2 and give the values of the constants A, B and C. (3 marks) d Using your answ er to part c or otherwise, find the maximum height of the diver, and the time at which this maximum height is reached. (2 marks) 12 For this question, f(x ) = 4kx2 + (4k + 2)x + 1, where k is a real constant. a Find the discriminant of f(x ) in terms of k. (3 marks) b By simplifying your answ er to part a or otherwise, prove that f(x) has two distinct real roots for all non-zero values of k. (2 marks) c Explain why f( x) cannot have two distinct real roots when k = 0. (1 mark) 13 Find all of the r oots of the function r(x) = x8 βˆ’ 17x4 + 16. (5 marks) 14 Lynn is selling cushions as part of an enterprise project. On her first attempt, she sold 80 cushions at the cost of Β£15 each. She hopes to sell more cushions next time. Her adviser suggests that she can expect to sell 10 more cushions for every Β£1 that she lowers the price. a The number of cushions sold c can be modelled by the equation c = 230 βˆ’ Hp, where Β£p is the price of each cushion and H is a constant. Determine the value of H. (1 mark) To model her tota l revenue, Β£r, Lynn multiplies the number of cushions sold by the price of each cushion. She writes this as r = p(230 βˆ’ Hp).b Rearrange r into the form A βˆ’ B( p βˆ’ C )2, where A, B and C are constants to be found. (3 marks) c Using your answ er to part b or otherwise, show that Lynn can increase her revenue by Β£122.50 through lowering her prices, and state the optimum selling price of a cushion. (2 marks)E E/P E/P E/P E/P E/P
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37Quadratics 1 To solve a quadratic equation by factorising: βˆ™ Write the equation in the f orm ax2 + bx + c = 0 βˆ™ Factorise the l eft-hand side βˆ™ Set each factor equal to z ero and solve to find the value(s) of x 2 The solutions of the equation ax2 + bx + c = 0 where a β‰  0 are given by the formula: x = βˆ’b Β± βˆšβ€―_______ b 2 βˆ’ 4ac _____________ 2a 3 x2 + bx = (x + b __ 2 ) 2 – ( b __ 2 ) 2 4 ax2 + bx + c = a (x + b ___ 2a ) 2 + (c – b2 ___ 4a2 ) 5 The set of possibl e inputs for a function is called the domain. The set of possible outputs of a function is called the range. 6 The roots of a function are the values of x for which f(x) = 0. 7 You can find the coor dinates of a turning point of a quadratic graph by completing the square. If f(x) = a(x + p)2 + q, the graph of y = f(x) has a turning point at (βˆ’p, q). 8 For the quadratic function f( x) = ax2 + bx + c = 0, the expression b2 βˆ’ 4ac is called the discriminant. The value of the discriminant shows how many roots f(x) has: βˆ™ If b2 βˆ’ 4ac . 0 then a quadratic function has two distinct real roots. βˆ™ If b2 βˆ’ 4ac = 0 then a quadratic function has one repeated real root. βˆ™ If b2 βˆ’ 4ac , 0 then a quadratic function has no real roots 9 Quadratics can be used to model r eal-life situations.Summary of key pointsa The ratio of the lengths a : b in this line is the same as the r atio of the lengths b : c. a b c Show that this ratio is 1 + βˆšβ€―__ 5 ______ 2 : 1. b Show also that the infinite squar e root βˆšβ€―_______________________ 1 + βˆšβ€―___________________ 1 + βˆšβ€―______________ 1 + βˆšβ€―__________ 1 + βˆšβ€―______ 1 + … = 1 + βˆšβ€―__ 5 ______ 2 Challenge
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38 Equations and inequalities After completing this chapter you should be able to: ● Solve linear simultaneous equations using elimination or substit ution β†’ pages 39 βˆ’ 40 ● Solve simultaneous equations: one linear and one quadratic β†’ pages 41 βˆ’ 42 ● Interpret algebraic solutions of equations graphically β†’ pages 42 βˆ’ 45 ● Solve linear inequalities β†’ pages 46 βˆ’ 48 ● Solve quadratic inequalities β†’ pages 48 βˆ’ 51 ● Interpret inequalities graphically β†’ pages 51 βˆ’ 53 ● Represent linear and quadratic inequalities graphically β†’ pages 53 βˆ’ 55Objectives 1 A = {factors of 12} B = {factors of 20} Write do wn the numbers in each of these sets: a A ∩ B b (A βˆͺ B)9 ← GCSE Mathematics 2 Simplify these expressions. a βˆšβ€―___ 75 b 2 βˆšβ€―___ 45 + 3 βˆšβ€―___ 32 ___________ 6 ← Section 1.5 3 Match the equations to the correct graph. Label the points of int ersection with the axes and the coordinates of the turning point. a y = 9 – x2 b y = (x – 2)2 + 4 c y = (x – 7)(2x + 5) y xii i y xiii y xO O O ← Section 2.47AB 9 116 1231 25 10 20 j 134Prior knowledge check Food scientists use regions on graphs to optimise athletes’ nutritional intake and ensure they satisfy the minimum dietary requirements for calories and vitamins.3
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39 Equations and inequalities 3.1 Linear simultaneous equations Linear simultaneous equations in two unknowns have one set of values that will make a pair of equations true at the same time. The solution to this pair of simultaneous equations is x = 5, y = 2 x + 3y = 11 (1) 4x – 5y = 10 (2) β–  Linear simultaneous equations can be solved using elimination or substit ution.5 + 3(2) = 5 + 6 = 11 βœ“ 4(5) – 5(2) = 20 – 10 = 10 βœ“ Example 1 Solve the simultaneous equations: a 2x + 3y = 8 b 4x βˆ’ 5y = 4 3x βˆ’ y = 23 6x + 2y = 25 a 2x + 3 y = 8 (1) 3x βˆ’ y = 23 (2) 9x βˆ’ 3y = 69 (3) 11x = 77 x = 7 14 + 3 y = 8 3y = 8 βˆ’ 14 y = βˆ’2 The solution is x = 7, y = βˆ’ 2. b 4x βˆ’ 5y = 4 (1) 6x + 2y = 25 (2) 12x βˆ’ 15 y = 12 (3) 12x + 4y = 50 (4) βˆ’19y = βˆ’38 y = 2 4x βˆ’ 10 = 4 4x = 14 x = 3 1 __ 2 The s olution is x = 3 1 __ 2 , y = 2.Remember to check your solution by substituting into equation (2). 3(7) – (βˆ’2) = 21 + 2 = 23 βœ“ Note that you could also multiply equation (1) by 3 and equation (2) by 2 to get 6x in both equations. You could then subtract to eliminate x. Multiply equation (1) by 3 and multiply equation (2) by 2 to get 12x in each equation. Subtract, since the 12x terms have the same sign (both positive). Substitute y = 2 into equation (1) to find x.First look for a way to eliminate x or y. Multiply equation (2) by 3 to get 3y in each equation. Number this new equation (3). Then add equations (1) and (3), since the 3y terms have different signs and y will be eliminated. Substitute x = 7 into equation (1) to find y.
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40 Chapter 3 Example 2 1 Solve these simultaneous equations by elimination: a 2x βˆ’ y = 6 b 7x + 3y = 16 c 5x + 2y = 6 4x + 3y = 22 2x + 9y = 29 3x βˆ’ 10y = 26 d 2x βˆ’ y = 12 e 3x βˆ’ 2y = βˆ’6 f 3x + 8y = 33 6x + 2y = 21 6x + 3y = 2 6x = 3 + 5y 2 Solve these simultaneous equa tions by substitution: a x + 3y = 11 b 4x βˆ’ 3y = 40 c 3x βˆ’ y = 7 d 2y = 2x βˆ’ 3 4x βˆ’ 7y = 6 2x + y = 5 10x + 3y = βˆ’2 3y = x βˆ’ 1 3 Solve these simultaneous equa tions: a 3x βˆ’ 2y + 5 = 0 b x βˆ’ 2 y ______ 3 = 4 c 3y = 5(x βˆ’ 2) 5(x + y) = 6(x + 1) 2x + 3y + 4 = 0 3(x βˆ’ 1) + y + 4 = 0 4 3x + ky = 8 x βˆ’ 2ky = 5 are simultaneous equa tions where k is a constant. a Show that x = 3. (3 marks) b Given tha t y = 1 _ 2 determine the value of k. (1 mark) 5 2x βˆ’ py = 5 4x + 5y + q = 0 are simultaneous equa tions where p and q are constants. The solution to this pair of simultaneous equa tions is x = q, y = βˆ’1. Find the value of p and the value of q. (5 marks) First rearrange bo th equations into the same form e.g. ax + by = c.Hint E/P k is a constant, so it has the same value in both equations.Problem-solving E/PExercise 3ASolve the simultaneous equations: 2x βˆ’ y = 1 4x + 2y = βˆ’30 2x βˆ’ y = 1 (1) 4x + 2y = βˆ’30 (2) y = 2x βˆ’ 1 4x + 2(2 x βˆ’ 1) = βˆ’ 30 4x + 4 x βˆ’ 2 = βˆ’ 30 8x = βˆ’28 x = βˆ’3 1 __ 2 y = 2(βˆ’3 1 __ 2 ) βˆ’ 1 = βˆ’8 The solution is x = βˆ’ 3 1 __ 2 , y = βˆ’8.Rearrange an equation, in this case equation (1), to get either x = … or y = … (here y = …). Solve for x. Substitute x = βˆ’3 1 _ 2 into equation (1) to find the value o f y.Substitute this into the other equation (here into equation (2) in place of y). Remember to check your solution in equation (2). 4(βˆ’3.5) + 2(βˆ’8) = βˆ’14 βˆ’ 16 = βˆ’30 βœ“
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41 Equations and inequalities 3.2 Quadratic simultaneous equations You need to be able to solve simultaneous equations where one equation is linear and one is quadratic. To solve simultaneous equations involving one linear equation and one quadratic equation, you need to use a substitution method from the linear equation into the quadratic equation. β–  Simultaneous equations with one linear and one quadratic equation can hav e up to two pairs of solutions. You need to make sure the solutions are paired correctly. The solutions to this pair of simultaneous equations are x = 4, y = –3 and x = 5.5, y = –1.5. x – y = 7 (1) y2 + xy + 2x = 5 (2)4 – (–3) = 7 βœ“ and 5.5 – (–1.5) = 7 βœ“ (–3)2 + (4)(–3) + 2(4) = 9 – 12 + 8 = 5 βœ“ and (–1.5)2 + (5.5)(– 1.5) + 2(5.5) = 2.25 – 8.25 + 11 = 5 βœ“ Example 3 Solve the simultaneous equations: x + 2y = 3 x2 + 3xy = 10 x + 2 y = 3 (1) x2 + 3 xy = 10 (2) x = 3 βˆ’ 2 y (3 βˆ’ 2 y)2 + 3y(3 βˆ’ 2 y) = 10 9 βˆ’ 12 y + 4 y2 + 9 y βˆ’ 6 y2 = 10 βˆ’2y2 βˆ’ 3y βˆ’ 1 = 0 2y2 + 3y + 1 = 0 (2y + 1)( y + 1) = 0 y = βˆ’ 1 __ 2 or y = βˆ’ 1 So x = 4 or x = 5 Solutions are x = 4, y = βˆ’ 1 __ 2 and x = 5, y = βˆ’ 1.Rearrange linear equation (1) to get x = … or y = … (here x = …). Substitute this into quadratic equation (2) (here in place of x ). Solve for y using factorisation. Find the corresponding x-values by substituting the y-values into linear equation (1), x = 3 – 2y. There are two solution pairs for x and y.The quadratic equation can contain terms involving y 2 and xy. (3 βˆ’ 2 y)2 means (3 βˆ’ 2 y)(3 βˆ’ 2 y) ← Section 1.2 1 Solve the simultaneous equations: a x + y = 11 b 2x + y = 1 c y = 3x xy = 30 x2 + y2 = 1 2y2 βˆ’ xy = 15 d 3a + b = 8 e 2u + v = 7 f 3x + 2y = 7 3a2 + b2 = 28 uv = 6 x2 + y = 8 2 Solve the simultaneous equa tions: a 2x + 2y = 7 b x + y = 9 c 5y βˆ’ 4x = 1 x2 βˆ’ 4y2 = 8 x2 βˆ’ 3xy + 2y2 = 0 x2 βˆ’ y2 + 5x = 41Exercise 3B
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42 Chapter 3 3 Solve the simultaneous equa tions, giving your answers in their simplest surd form: a x βˆ’ y = 6 b 2x + 3y = 13 xy = 4 x2 + y2 = 78 4 Solve the simultaneous equa tions: x + y = 3 x2 βˆ’ 3y = 1 (6 marks) 5 a By eliminating y from the equations y = 2 βˆ’ 4x 3x2 + xy + 11 = 0 show that x2 βˆ’ 2x – 11 = 0. (2 marks) b Hence, or otherwise, solv e the simultaneous equations y = 2 βˆ’ 4x3x 2 + xy + 11 = 0 giving your answers in the form a Β± b βˆšβ€―__ 3 , where a and b are integers. (5 marks) 6 One pair of solutions for the sim ultaneous equations y = kx βˆ’ 5 4x2 βˆ’ xy = 6 is (1, p) where k and p are constants. a Find the values of k and p. b Find the second pair of solutions for the sim ultaneous equations. Use b rackets when you are substituting an expression into an equation.Watch out E/P E/P P If (1, p ) is a solution, then x = 1, y = p satisfies both equations.Problem-solving 3.3 Simultaneous equations on graphs You can represent the solutions of simultaneous equations graphically. As every point on a line or curve satisfies the equation of that line or curve, the points of intersection of two lines or curves satisfy both equations simultaneously. β–  The solutions to a pair o f simultaneous equations represent the points of intersection of their graphs. Example 4 a On the same axes, dr aw the graphs of: 2x + 3y = 8 3x βˆ’ y = 23 b Use your gra ph to write down the solutions to the simultaneous equations.y βˆ’ x = k x2 + y2 = 4 Given that the simultaneous equations have exactly one pair of solutions, show that k = Β± 2 βˆšβ€―__ 2 Challenge
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43 Equations and inequalities a –2 –/four.ss01 /four.ss01 8 2 6y x123/four.ss01 –1 –2 –3 –/four.ss012x + 3 y = 8 3x – y = 23O b The solution is (7, βˆ’2) or x = 7, y = βˆ’2.The point of intersection is the solution to the simultaneous equations 2x + 3y = 8 3x – y = 23 This solution matches the algebraic solution to the simultaneous equations. Example 5 a On the same axes, dr aw the graphs of: 2x + y = 3 y = x2 βˆ’ 3x + 1 b Use your gra ph to write down the solutions to the simultaneous equations. a y x –1–2–11 234 5 –31 O23456 (–1, 5) (2, –1) –2–3y = x2 – 3x + 1 2x + y = 3 b The solutions are ( βˆ’1, 5 ) or x = βˆ’ 1, y = 5 and (2, βˆ’ 1) or x = 2, y = βˆ’ 1.There are two solutions. Each solution will have an x-value and a y-value. Check your solutions by substituting into both equations. 2(βˆ’1) + (5) = βˆ’2 + 5 = 3 βœ“ and 5 = (βˆ’1)2 – 3(βˆ’1) + 1 = 1 + 3 + 1 = 5 βœ“ 2(2) + (βˆ’1) = 4 βˆ’ 1 = 3 βœ“ and βˆ’1 = (2) 2 – 3(2) + 1 = 4 βˆ’ 6 + 1 = βˆ’1 βœ“ The graph of a linear equation and the graph of a quadratic equation can either: β€’ intersect twice β€’ intersect once β€’ not intersect Aft er substituting, you can use the discriminant of the resulting quadratic equation to determine the number of points of intersection. Find the point of intersection gr aphically using GeoGebra.Online Plot the curve and the line using Ge oGebra to find the two points of intersection.Online
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44 Chapter 3 β–  For a pair of simultaneous equations that produce a quadratic equation of the form ax2 + bx + c = 0: β€’ b2 – 4ac > 0 β€’ b2 – 4ac = 0 β€’ b2 – 4ac < 0 two real solutions one real solution no real solutions Example 6 The line with equation y = 2x + 1 meets the curve with equation kx2 + 2y + (k – 2) = 0 at exactly one point. Given that k is a positive constant a find the value of k b for this va lue of k, find the coordinates of the point of intersection. a y = 2x + 1 (1) kx2 + 2 y + ( k – 2) = 0 (2) kx2 + 2(2 x + 1) + ( k – 2) = 0 kx2 + 4 x + 2 + k – 2 = 0 kx2 + 4 x + k = 0 42 – 4 Γ— k Γ— k = 0 16 – 4k2 = 0 k2 – 4 = 0 (k – 2)( k + 2) = 0 k = 2 or k = βˆ’ 2 So k = 2 b 2x2 + 4 x + 2 = 0 x2 + 2x + 1 = 0 (x + 1)(x + 1) = 0 x = βˆ’1 y = 2(–1) + 1 = – 1 Point of intersection is ( –1, –1).Substitute y = 2x + 1 into equation (2) and simplify the quadratic equation. The resulting quadratic equation is in the form ax 2 + bx + c = 0 with a = k, b = 4 and c = k. Factorise the quadratic to find the values of k. The solution is k = +2 as k is a positive constant. Substitute k = +2 into the quadratic equation kx 2 + 4x + k = 0. Simplify and factorise to find the x-coordinate. Check your answer by substituting into equation (2): 2x2 + 2y = 0 2(–1)2 + 2(–1) = 2 – 2 = 0 βœ“You are told that the line meets the curve at exactly one point, so use the discriminant of the resulting quadratic. There will be exactly one solution, so b 2 – 4ac = 0.Problem-solving Substitute x = –1 into linear equation (1) to find the y-coordinate. Explore how the value of k affects the l ine and the curve using GeoGebra.Online
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45 Equations and inequalities 1 In each case: i draw the gr aphs for each pair of equations on the same axes ii find the coordinates of the point of intersection. a y = 3x – 5 b y = 2x – 7 c y = 3x + 2 y = 3 – x y = 8 – 3x 3x + y + 1 = 0 2 a Use graph paper to draw accurately the graphs of 2y = 2x + 11 and y = 2x2 βˆ’ 3x – 5 on the same axes. b Use your graph to find the coordinates of the points of intersection. c Verify your solutions b y substitution. 3 a On the same axes sketch the curv e with equation x2 + y = 9 and the line with equation 2x + y = 6. b Find the coordinates of the points of intersection. c Verify your solutions b y substitution. 4 a On the same axes sketch the curv e with equation y = (x – 2)2 and the line with equation y = 3x – 2. b Find the coordinates of the point of intersection. 5 Find the coordinates of the points at which the line with equation y = x βˆ’ 4 intersects the curve with equation y2 = 2x2 βˆ’ 17. 6 Find the coordinates of the points at which the line with equation y = 3x βˆ’ 1 intersects the curve with equation y2 = xy + 15. 7 Determine the number of points of intersection for these pairs of simultaneous equations. a y = 6x2 + 3x βˆ’ 7 b y = 4x2 – 18x + 40 c y = 3x2 – 2x + 4 y = 2x + 8 y = 10x – 9 7x + y + 3 = 0 8 Given the sim ultaneous equations 2x – y = 1x 2 + 4ky + 5k = 0 where k is a non-zero constant a show that x2 + 8kx + k = 0. (2 marks) Given tha t x2 + 8kx + k = 0 has equal roots, b find the value of k (3 marks) c for this va lue of k, find the solution of the simultaneous equations. (3 marks) 9 A swimmer div es into a pool. Her position, p m, underwater can be mode lled in relation to her horizontal distance, x m, from the point she entered the water as a quadratic equation p = 1 _ 2 x2 – 3x. The position of the bottom of the pool can be modelled by the linear equation p = 0.3x – 6. Determine whether this model predicts that the swimmer will touch the bottom of the pool. (5 marks) You need to use algebra in par t b to find the coordinates.Hint P E/P E/P p xExercise 3C
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46 Chapter 3 3.4 Linear inequalities You can solve linear inequalities using similar methods to those for solving linear equations. β–  The solution of an inequality is the set o f all real numbers x that make the inequality true. Example 7 Find the set of values of x for which: a 5x + 9 > x + 20 b 12 βˆ’ 3 x < 27 c 3(x βˆ’ 5) > 5 βˆ’ 2(x βˆ’ 8) a 5x + 9 > x + 20 4x + 9 > 20 4x > 11 x > 2.75 b 12 – 3x < 27 –3x < 15 x > –5 c 3(x – 5) > 5 – 2( x – 8) 3x – 15 > 5 – 2x + 16 5x > 5 + 16 + 15 5x > 36 x > 7.2Subtract 12 from both sides. Divide both sides by βˆ’3. (You therefore need to turn round the inequality sign.) In set notation {x : x > βˆ’5}. Multiply out (note: βˆ’2 Γ— βˆ’8 = +16).Rearrange to get x > …In set notation {x : x > 7.2}. –6 –4 –2 0 2 4 6 Here the solution sets are x < βˆ’1 or x > 3. –6 –4 –2 0 2 4 6Here there is no overlap and the two inequalities have to be written separately as x < βˆ’1 or x > 3.β—‹ is used for < and > and means the end value is not included. ● is used for < and > and means the end value is included. These are the only real values that satisfy both equalities simultaneously so the solution is βˆ’2 < x < 4.You may sometimes need to find the set of values for which two inequalities are true together. Number lines can be useful to find your solution. For example, in the number line below the solution set is x > βˆ’2 and x < 4. In se t notation x > βˆ’2 and x < 4 is written { x : βˆ’2 < x < 4} or alternatively { x : x > βˆ’2} β‹‚ { x : x < 4} x < βˆ’1 or x > 3 is written { x : x < βˆ’1} ⋃ { x : x > 3}Notation You c an write the solution to this inequality using set notation as { x : x > 2.75}. This means the set of all values x for which x is greater than or equal to 2.75.Notation Rearrange to get x > …
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47 Equations and inequalities Example 8 Find the set of values of x for which: a 3x βˆ’ 5 < x + 8 and 5x > x βˆ’ 8 b x – 5 > 1 – x or 15 – 3x > 5 + 2x. c 4x + 7 > 3 and 17 < 11 + 2x. a 3x – 5 < x + 8 5x > x – 8 2x – 5 < 8 4x > – 8 2x < 13 x > –2 x < 6.5 –/four.ss01 –2 0 /four.ss01 2 6 8 x < 6.5 x > –2 So the required set of values is – 2 < x < 6.5. b x – 5 > 1 – x 15 – 3x > 5 + 2x 2x – 5 > 1 10 – 3x > 2x 2x > 6 10 > 5x x > 3 2 > x x < 2 x < 3 x > 2–/four.ss01 –2 0 /four.ss01 2 6 8 The solution is x > 3 or x < 2.Draw a number line to illustrate the two inequalities. The two sets of values overlap (intersect) where βˆ’2 < x < 6.5. Notice here how this is written when x lies between two values. In set notation this can be written as {x : βˆ’2 < x < 6.5}. Draw a number line. Note that there is no overlap between the two sets of values. In set notation this can be written as {x : x < 2} ⋃ {x : x > 3}. 1 Find the set of va lues of x for which: a 2x βˆ’ 3 < 5 b 5x + 4 > 39 c 6x βˆ’ 3 > 2x + 7 d 5x + 6 < βˆ’12 βˆ’ x e 15 βˆ’ x > 4 f 21 βˆ’ 2 x > 8 + 3x g 1 + x < 25 + 3x h 7x βˆ’ 7 < 7 βˆ’ 7x i 5 βˆ’ 0.5 x > 1 j 5x + 4 > 12 βˆ’ 2xExercise 3D
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48 Chapter 3 3.5 Quadratic inequalities β–  To solve a quadratic inequality: β€’ Rearr ange so that the right-hand side of the inequality is 0 β€’ Solve the corresponding quadratic equation to find the critical values β€’ Sketch the graph of the quadratic function β€’ Use your sketch to find the required set of values. The sketch shows the graph of f(x) = x2 – 4x βˆ’ 5 = (x + 1)(x – 5) –1 5y x OThe solutions to the quadratic inequality x2 – 4x – 5 > 0 are the x-values when the curve is above the x-axis (the darker part of the curve). This is when x < βˆ’1 or x > 5. In set notation the solution is {x : x < βˆ’1} ⋃ {x : x > 5}. The solutions to the quadratic inequality x 2 – 4x – 5 < 0 are the x-values when the curve is below the x-axis (the lighter part of the curve). This is when x > βˆ’1 and x < 5 or –1 < x < 5. In set notation the solution is {x : βˆ’1 < x < 5}.The solutions to f(x) = 0 are x = βˆ’1 and x = 5. These are called the critical values.A = { x : 3x + 5 > 2} B = { x : x __ 2 + 1 < 3 } C = { x : 11 < 2x βˆ’ 1} Given that A β‹‚ ( B ⋃ C ) = {x : p < x < q } ⋃ {x : x > r }, find the values of p , q and r .Challenge2 Find the set of va lues of x for which: a 2(x βˆ’ 3) > 0 b 8(1 βˆ’ x) > x βˆ’ 1 c 3(x + 7) < 8 βˆ’ x d 2(x βˆ’ 3) βˆ’ (x + 12) < 0 e 1 + 11(2 βˆ’ x) < 10(x βˆ’ 4) f 2(x βˆ’ 5) > 3(4 βˆ’ x) g 12x βˆ’ 3(x βˆ’ 3) < 45 h x βˆ’ 2(5 + 2x) < 11 i x(x βˆ’ 4) > x2 + 2 j x(5 βˆ’ x) > 3 + x βˆ’ x2 k 3x + 2x(x βˆ’ 3) < 2(5 + x2) l x(2x βˆ’ 5) < 4x( x + 3) ________ 2 βˆ’ 9 3 Use set notation to describe the set of v alues of x for which: a 3(x βˆ’ 2) > x βˆ’ 4 and 4x + 12 > 2x + 17 b 2x βˆ’ 5 < x βˆ’ 1 and 7(x + 1) > 23 βˆ’ x c 2x βˆ’ 3 > 2 and 3(x + 2) < 12 + x d 15 βˆ’ x < 2(11 βˆ’ x) and 5(3x βˆ’ 1) > 12x + 19 e 3x + 8 < 20 and 2(3x βˆ’ 7) > x + 6 f 5x + 3 < 9 or 5(2x + 1) > 27 g 4(3x + 7) < 20 or 2(3x βˆ’ 5) > 7 βˆ’ 6 x ______ 2
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49 Equations and inequalities Example 9 Find the set of values of x for which: 3 βˆ’ 5x βˆ’ 2x2 < 0. 3 βˆ’ 5 x βˆ’ 2x2 = 0 2x2 + 5 x βˆ’ 3 = 0 (2x βˆ’ 1)( x + 3) = 0 x = 1 __ 2 or x = βˆ’ 3 –3 1 2xy O So the required set of values is x < βˆ’3 or x > 1 __ 2 .Multiply by βˆ’1 (so it’s easier to factorise). 1 _ 2 and βˆ’3 ar e the critical values. Draw a sketch to show the shape of the graph and the critical values. Since the coefficient of x2 is negative, the graph is β€˜upside-down ⋃-shaped’. It crosses the x-axis at βˆ’3 and 1 _ 2 . ← Section 2.4 3 βˆ’ 5x βˆ’ 2x2 < 0 ( y < 0) for the outer parts of the graph, belo w the x-axis, as shown by the paler parts of the curve. In set notation this can be written as {x : x < βˆ’3} ⋃ {x : x > 1 _ 2 }.Quadratic equation. Example 10 a Find the set of va lues of x for which 12 + 4x > x2. b Hence find the set of va lues for which 12 + 4x > x2 and 5x – 3 > 2. a 12 + 4x > x2 0 > x2 βˆ’ 4 x βˆ’ 12 x2 βˆ’ 4 x βˆ’ 12 < 0 x2 βˆ’ 4 x βˆ’ 12 = 0 (x + 2)( x βˆ’ 6) = 0 x = βˆ’2 or x = 6 Sketch of y = x2 βˆ’ 4 x βˆ’ 12 –26 xy O x2 βˆ’ 4 x βˆ’ 12 < 0 Solution: βˆ’ 2 < x < 6You can use a table to check your solution. βˆ’2 < x < 6 Use the critical values to split the real number line into sets. –26 x < βˆ’2 βˆ’2 < x < 6 x > 6 x + 2 βˆ’ + + x βˆ’ 6 βˆ’ βˆ’ + (x + 2)(x βˆ’ 6) + βˆ’ + For each set, check whether the set of values makes the value of the bracket positive or negative. For example, if x < βˆ’2, (x + 2) is negative, (x – 6) is negative, and (x + 2)(x – 6) is (neg) Γ— (neg) = positive. In set notation the solution is {x : βˆ’2 < x < 6}.
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50 Chapter 3 Example 11 Find the set of values for which 6 __ x > 2 , x β‰  0b Solving 12 + 4 x > x2 gives βˆ’ 2 < x < 6. Solving 5 x βˆ’ 3 > 2 gives x > 1. –/four.ss01–202/four.ss0168 –2 < x < 6 x > 1 The two sets of values overlap where 1 < x < 6. So the solution is 1 < x < 6. 6 __ x > x 6x > 2x2 6x βˆ’ 2x2 > 0 6x βˆ’ 2x2 = 0 x(6 βˆ’ 2 x) = 0 x = 0 or x = 3 3xy O The solution is 0 < x < 3. 1 Find the set of va lues of x for which: a x2 βˆ’ 11x + 24 < 0 b 12 βˆ’ x βˆ’ x2 > 0 c x2 βˆ’ 3x βˆ’ 10 > 0 d x2 + 7x + 12 > 0 e 7 + 13 x βˆ’ 2x2 > 0 f 10 + x βˆ’ 2x2 < 0 g 4x2 βˆ’ 8x + 3 < 0 h βˆ’2 + 7x βˆ’ 3x2 < 0 i x2 βˆ’ 9 < 0 j 6x2 + 11x βˆ’ 10 > 0 k x2 βˆ’ 5x > 0 l 2x2 + 3x < 0 2 Find the set of va lues of x for which: a x2 < 10 βˆ’ 3x b 11 < x2 + 10 c x(3 βˆ’ 2x) > 1 d x(x + 11) < 3(1 βˆ’ x2)Exercise 3EThis question is easier if you represent the information in more than one way. Use a sketch graph to solve the quadratic inequality, and use a number line to combine it with the linear inequality.Problem-solving In set notation this can be written as {x : 1 < x < 6}. Solve the corresponding quadratic equation to find the critical values. Sketch y = x (6 – 2 x). You are interested in the values of x where the graph is above the x -axis.x = 0 can still be a critical value even though xΒ β‰ Β 0. But it would not be part of the solution set, even if the inequality was > rather than > . x cou ld be either positive or negative, so you can’t multiply both sides of this inequality by x . Instead, multiply both sides by x 2. Because x2 is never negative, and x β‰  0 so x2 β‰  0, the inequality sign stays the same.Watch out
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51 Equations and inequalities 3 Use set notation to describe the set of v alues of x for which: a x2 βˆ’ 7x + 10 < 0 and 3x + 5 < 17 b x2 βˆ’ x βˆ’ 6 > 0 and 10 βˆ’ 2x < 5 c 4x2 βˆ’ 3x βˆ’ 1 < 0 and 4(x + 2) < 15 βˆ’ (x + 7) d 2x2 βˆ’ x βˆ’ 1 < 0 and 14 < 3x βˆ’ 2 e x2 βˆ’ x βˆ’ 12 > 0 and 3x + 17 > 2 f x2 βˆ’ 2x βˆ’ 3 < 0 and x2 βˆ’ 3x + 2 > 0 4 Given tha t x β‰  0, find the set of values of x for which: a 2 __ x < 1 b 5 > 4 __ x c 1 __ x + 3 > 2 d 6 + 5 __ x > 8 __ x e 25 > 1 ___ x 2 f 6 ___ x 2 + 7 __ x < 3 5 a Find the range of values of k for which the equation x2 βˆ’ kx + (k + 3) = 0 has no real roots. b Find the range of v alues of p for which the roots of the equation px2 + px βˆ’ 2 = 0 are real. 6 Find the set of va lues of x for which x2 βˆ’ 5x βˆ’ 14 > 0. (4 marks) 7 Find the set of va lues of x for which a 2(3x βˆ’ 1) < 4 – 3x (2 marks) b 2x2 – 5x – 3 < 0 (4 marks) c both 2(3x – 1) < 4 – 3x and 2x2 – 5x – 3 < 0. (2 marks) 8 Given tha t x β‰  3, find the set of values for which 5 _____ x – 3 < 2 . (6 marks) 9 The equation kx2 – 2kx + 3 = 0, where k is a constant, has no real roots. Prove that k satisfies the inequality 0 < k < 3. (4 marks)P The quadratic equation ax2 + bx + c = 0 has real roots if b2 βˆ’ 4ac > 0. ← Section 2.5Hint E E Multiply both sides of the inequality by ( x βˆ’ 3)2.Problem-solvingE/P E/P 3.6 Inequalities on graphs You may be asked to interpret graphically the solutions to inequalities by considering the graphs of functions that are related to them. β–  The values of x for which the curve y = f(x) is below the curve y = g(x) satisfy the inequality f(x) < g( x). β–  The values of x for which the curve y = f(x) is above the curve y = g(x) satisfy the inequality f(x) > g( x).
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52 Chapter 3 Example 12 L1 has equation y = 12 + 4x. L2 has equation y = x2. The diagram shows a sketch of L1 and L2 on the same axes. a Find the coordinates of P1 and P2, the points of intersection. b Hence write down the solution to the inequality 12 + 4x > x2.y x OL1: y = 12 + 4x L2: y = x2P1 P2 a x2 = 12 + 4 x x2 βˆ’ 4 x βˆ’ 12 = 0 (x βˆ’ 6)( x + 2) = 0 x = 6 and x = βˆ’ 2 substitute into y = x2 when x = 6, y = 36 P1 (6, 36) when x = βˆ’ 2, y = 4 P2 (βˆ’2, 4) b 12 + 4x > x2 when the graph of L1 is above the graph of L2 βˆ’2 < x < 6This is the range of values of x for which the graph of y = 12 + 4x is above the graph of y = x2 i.e. between the two points of intersection. In set notation this is {x : βˆ’2 < x < 6}.Equate to find the points of intersection, then rearrange to solve the quadratic equation. Factorise to find the x-coordinates at the points of intersection. 1 L1 has equation 2y + 3x = 6. L2 has the equation x βˆ’ y = 5. The diagram shows a sketch of L1 and L2. a Find the coordinates of P, the point of intersection. b Hence write down the solution to the inequality 2 y + 3x > x – y.y x O L1: 2y + 3x = 6L2: x – y = 5Exercise 3Fy x 2 5 Oy = g(x)y = f(x) The solutions to f(x) = g(x) are x = 2 and x = 5.f(x) is below g(x) when 2 < x < 5. These values of x satisfy f(x) < g(x).f(x) is above g(x) when x < 2 and when x > 5. These values of x satisfy f(x) > g(x).
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53 Equations and inequalities The sketch shows the graphs of f(x) = x2 – 4x βˆ’ 12 g(x) = 6 + 5 x βˆ’ x2 a Find the coordinates of the points of intersection. b Fin d the set of values of x for which f( x) < g( x). Give your answer in set notation.y x O y = g(x)y = f (x)Challenge All the shaded points in this region satisfy the inequality y > f(x).3.7 Regions You can use shading on graphs to identify regions that satisfy linear and quadratic inequalities. β–  y < f(x) represents the points on the coordinate grid below the curve y = f(x). β–  y > f(x) represents the points on the coordinate grid above the curve y = f(x). y = f (x)y x OAll the unshaded points in this region satisfy the inequality y < f(x).2 For each pair of functions: i Sketch the gra phs of y = f(x) and y = g(x) on the same axes. ii Find the coordinates of any points of intersection. iii Write down the solutions to the inequa lity f(x) < g(x). a f(x ) = 3x – 7 b f(x ) = 8 – 5x c f(x ) = x2 + 5 g(x ) = 13 – 2x g(x ) = 14 – 3x g(x) = 5 – 2x d f(x ) = 3 – x2 e f(x ) = x2 – 5 f f(x ) = 7 – x2 g(x ) = 2x – 12 g(x) = 7x + 13 g(x) = 2x – 8 3 Find the set of va lues of x for which the curve with equation y = f(x) is below the line with equation y = g(x).a f(x ) = 3x2 βˆ’ 2x – 1 b f(x ) = 2x2 – 4x + 1 c f(x ) = 5x – 2x2 – 4 g(x ) = x + 5 g(x) = 3x – 2 g(x) = βˆ’2x – 1 d f(x ) = 2 __ x , x β‰  0 e f(x) = 3 __ x2 βˆ’ 4 __ x , x β‰  0 f f(x) = 2 _____ x + 1 , x β‰  βˆ’1 g(x ) = 1 g(x) = βˆ’1 g(x) = 8P
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54 Chapter 3 β–  If y > f(x) or y < f(x) then the curve y = f(x) is not included in the region and is represented by a dotted line. β–  If y > f(x) or y < f(x) then the curve y = f(x) is included in the region and is represented by a solid line. Example 13 On graph paper, shade the region that satisfies the inequalities: y > βˆ’2, x < 5, y < 3x + 2 and x > 0. y x –5–2 –1 1234 567 –35 O10152025x = 0 x = 5 y = 3x + 2 y = –2Draw dotted lines for x = 0, x = 5. Draw solid lines for y = βˆ’2, y = 3x + 2.Shade the required region. Test a point in the region. Try (1, 2).For x = 1: 1 < 5 and 1 > 0 βœ“For y = 2: 2 > βˆ’2 and 2 < 3 + 2 βœ“ Example 14 On graph paper, shade the region that satisfies the inequalities: 2y + x < 14 y > x2 – 3x – 4 y x –5–1 12 3/four.ss01 567 –2 –3 –/four.ss015 O1015202530 –10y = x2 – 3x – /four.ss01 2y + x = 1/four.ss01Draw a dotted line for 2y + x = 14 and a solid line for y = x2 – 3x – 4. Shade the required region.Test a point in the region. Try (0, 0). 0 + 0 < 14 and 0 > 0 – 0 – 4 βœ“ Explore which regions on the g raph satisfy which inequalities using GeoGebra.Online
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55 Equations and inequalities 1 On a coordinate grid, shade the r egion that satisfies the inequalities: y > x – 2, y < 4x and y < 5 – x. 2 On a coordinate grid, shade the r egion that satisfies the inequalities: x > βˆ’1, y + x < 4, 2x + y < 5 and y > βˆ’2. 3 On a coordinate grid, shade the r egion that satisfies the inequalities: y > (3 – x)(2 + x) and y + x > 3. 4 On a coordinate grid, shade the r egion that satisfies the inequalities: y > x2 – 2 and y < 9 – x2. 5 On a coordinate grid, shade the r egion that satisfies the inequalities: y > (x – 3)2, y + x > 5 and y < x – 1. 6 The sketch shows the gr aphs of the straight lines with equations: y = x + 1, y = 7 – x and x = 1. a Work out the coor dinates of the points of intersection of the functions. b Write down the set of inequalities that represent the shaded region shown in the sketch. 7 The sketch shows the gr aphs of the curves with equations: y = 2 – 5x – x2, 2x + y = 0 and x + y = 4. Write down the set of inequalities that represent the shaded region shown in the sketch. 8 a On a coordinate grid, shade the r egion that satisfies the inequalities y < x + 4, y + 5x + 3 > 0, y > βˆ’1 and x < 2. b Work out the coor dinates of the vertices of the shaded region. c Which of the v ertices lie within the region identified by the inequalities? d Work out the ar ea of the shaded region.Oy x –1–2–12 4 613 5712345678 y = 7 – xy = x + 1x = 1 Oy x–1 –2–3 1 –4–5–6 –2 2312345678 –1P A vertex is only included if both intersecting lines are included.Problem-solvingExercise 3G
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56 Chapter 3 1 2kx βˆ’ y = 4 4kx + 3y = βˆ’2 are two simultaneous equations, where k is a constant.a Show that y = βˆ’2. (3 marks) b Find an expression f or x in terms of the constant k. (1 mark) 2 Solve the simultaneous equa tions: x + 2y = 3 x2 βˆ’ 4y2 = βˆ’33 (7 marks) 3 Given the sim ultaneous equations x βˆ’ 2y = 13xy βˆ’ y 2 = 8 a Show that 5 y2 + 3y βˆ’ 8 = 0. (2 marks) b Hence find the pairs (x, y) for which the simultaneous equations are satisfied. (5 marks) 4 a By eliminating y from the equations x + y = 2x 2 + xy βˆ’ y2 = βˆ’1 show that x2 βˆ’ 6x + 3 = 0. (2 marks) b Hence, or otherwise solve the sim ultaneous equations x + y = 2 x2 + xy βˆ’ y2 = βˆ’1 giving x and y in the form a Β± b βˆšβ€―__ 6 , where a and b are integers. (5 marks) 5 a Given tha t 3x = 9y βˆ’ 1, show that x = 2y βˆ’ 2. (1 mark) b Solve the simultaneous equa tions: x = 2y βˆ’ 2 x2 = y2 + 7 (6 marks) 6 Solve the simultaneous equa tions: x + 2y = 3x 2 βˆ’ 2y + 4y2 = 18 (7 marks) 7 The curve and the line giv en by the equations kx2 βˆ’ xy + (k + 1)x = 1 βˆ’ k __ 2 x + y = 1 where k is a non-zero constant, intersect at a single point. a Find the value of k. (5 marks) b Give the coor dinates of the point of intersection of the line and the curve. (3 marks)E E E E E E E/PMixed exercise 3
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57 Equations and inequalities 8 A person throws a ba ll in a sports hall. The height of the ball, h m, h x can be modelled in relation to the horizontal distance from the point it was thrown from by the quadratic equation: h = βˆ’ 3 __ 10 x2 + 5 _ 2 x + 3 _ 2 The hall has a sloping ceiling which can be mode lled with equation h = 15 __ 2 βˆ’ 1 _ 5 x. Determine w hether the model predicts that the ball will hit the ceiling. (5 marks) 9 Give y our answers in set notation. a Solve the inequality 3 x βˆ’ 8 > x + 13. (2 marks) b Solve the inequality x2 βˆ’ 5x βˆ’ 14 > 0. (4 marks) 10 Find the set of va lues of x for which (x βˆ’ 1)(x βˆ’ 4) < 2(x βˆ’ 4). (6 marks) 11 a Use algebr a to solve (x βˆ’ 1)(x + 2) = 18. (2 marks) b Hence, or otherwise, find the set of values of x for which (x βˆ’ 1)(x + 2) > 18. Give your answer in set notation. (2 marks) 12 Find the set of va lues of x for which: a 6x βˆ’ 7 < 2x + 3 (2 marks) b 2x2 βˆ’ 11x + 5 < 0 (4 marks) c 5 < 20 ___ x (4 marks) d both 6x βˆ’ 7 < 2x + 3 and 2x2 βˆ’ 11x + 5 < 0. (2 marks) 13 Find the set of va lues of x that satisfy 8 __ x2 + 1 < 9 __ x , x β‰  0 (5 marks) 14 Find the values of k for which kx2 + 8x + 5 = 0 has real roots. (3 marks) 15 The equation 2x2 + 4kx βˆ’ 5k = 0, where k is a constant, has no real roots. Prove that k satisfies the inequality βˆ’ 5 _ 2 < k < 0. (3 marks) 16 a Sketch the gra phs of y = f(x) = x2 + 2x – 15 and g(x) = 6 βˆ’ 2x on the same axes. (4 marks) b Find the coordinates of any points of intersection. (3 marks) c Write down the set of values of x for which f(x) > g(x). (1 mark) 17 Find the set of va lues of x for which the curve with equation y = 2x2 + 3x βˆ’ 15 is below the line with equation y = 8 + 2x. (5 marks) 18 On a coordinate grid, shade the r egion that satisfies the inequalities: y > x2 + 4x – 12 and y < 4 – x2. (5 marks) 19 a On a coordinate grid, shade the r egion that satisfies the inequalities y + x < 6, y < 2x + 9, y > 3 and x > 0. (6 marks) b Work out the ar ea of the shaded region. (2 marks)E/P E E E E E E/P E E E E/P
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58 Chapter 3 1 Find the possible values of k for the quadratic equation 2 kx2 + 5kx + 5k βˆ’ 3 = 0 to have real roots. 2 A strai ght line has equation y = 2 x – k and a parabola has equation y = 3 x2 + 2kx + 5 where k is a constant. Find the range of values of k for which the line and the parabola do not intersect.Challenge 1 Linear simultaneous equations can be solved using elimination or substit ution. 2 Simultaneous equations with one linear and one quadratic equation can hav e up to two pairs of solutions. You need to make sure the solutions are paired correctly. 3 The solutions of a pair o f simultaneous equations represent the points of intersection of their graphs. 4 For a pair o f simultaneous equations that produce a quadratic equation of the form ax2 + bx + c = 0: ‒ b2 – 4ac > 0 two r eal solutions ‒ b2 – 4ac = 0 one real solution ‒ b2 – 4ac < 0 no real solutions 5 The solution of an inequality is the set o f all real numbers x that make the inequality true. 6 To solve a quadr atic inequality: ‒  Rearrange  so that the right-hand  side of the inequality  is 0 ‒  Solv e the corr esponding  quadratic  equation to find the critical values ‒  Sketch the graph of the quadratic  function ‒  Use your sket ch to find the requir ed set of values . 7 The values of x for which the curve y = f(x) is below the curve y = g(x) satisfy the inequality f(x) < g(x). The values of x for which the curve y = f(x) is above the curve y = g(x) satisfy the inequality f(x) > g(x). 8 y < f(x) represents the points on the coordinate grid below the curve y = f(x). y > f(x) represents the points on the coordinate grid above the curve y = f(x). 9 If y > f(x) or y < f(x) then the curve y = f(x) is not included in the region and is represented by a dotted line. If y > f(x) or y < f(x) then the curve y = f(x) is included in the region and is represented by a solid line.Summary of key points
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59 Graphs and transformations After completing this chapter you should be able to: ● Sketch cubic gr aphs β†’ pages 60 βˆ’ 64 ● Sketch quartic graphs β†’ pages 64 βˆ’ 66 ● Sketch reciprocal graphs of the form y = a __ x and y = a __ x2 β†’ pages 66 βˆ’ 67 ● Use intersection points of graphs to solve equations β†’ pages 68 βˆ’ 71 ● Translate graphs β†’ pages 71 βˆ’ 75 ● Stretch graphs β†’ pages 75 βˆ’ 78 ● Transform graphs of unfamiliar functions β†’ pages 79 βˆ’ 81Objectives 1 Factorise these quadratic expressions: a x2 + 6x + 5 b x2 – 4x + 3 ← GCSE Mathematics 2 Sketch the graphs of the following functions: a y = (x + 2)(x – 3) b y = x2 – 6x – 7 ← Section 2.4 3 a Copy and complete the table of values for the function y = x3 + x – 2. x–2 –1.5 –1–0.5 0 0.5 1 1.5 2 y–12–6.875 –2–1.375 b Use your table o f values to draw the graph of y = x3 + x – 2. ← GCSE Mathematics 4 Solve each pair of simultaneous equations: a y = 2x b y = x2 x + y = 7 y = 2x + 1 ← Sections 3.1, 3.2Prior knowledge check Many complicated functions can be understood by transforming simpler functions using stretches, reflections and translations. Particle physicists compare observed results with transformations of known functions to determine the nature of subatomic particles.4
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60 Chapter 4 4.1 Cubic graphs A cubic function has the form f(x) = ax3 + bx2 + cx + d, where a, b, c and d are real numbers and a is non-zero. The graph of a cubic function can take several different forms, depending on the exact nature of the function. Oy x Oy x Oy x Oy x β–  If p is a root of the function f( x), then the graph of y = f(x) touches or crosses the x-axis at the point ( p, 0). You can sketch the graph of a cubic function by finding the roots of the function.For these two functions a is positive. For these two functions a is negative. Example 1 Sketch the curves with the following equations and show the points where they cross the coordinate axes. a y = (x βˆ’ 2)(1 βˆ’ x)(1 + x) b y = x(x + 1)(x + 2) a y = (x – 2)(1 – x )(1 + x ) 0 = (x βˆ’ 2)(1 βˆ’ x )(1 + x ) So x = 2, x = 1 or x = βˆ’ 1 So the curve crosses the x -axis at (2, 0), (1, 0) and ( βˆ’1, 0). When x = 0, y = βˆ’ 2 Γ— 1 Γ— 1 = βˆ’ 2 So the curve crosses the y -axis at (0, βˆ’ 2). x β†’ ∞ , y β†’ βˆ’ ∞ x β†’ βˆ’βˆž, y β†’ ∞ 2 1 O –2–1 xy b y = x(x + 1)( x + 2) 0 = x(x + 1)( x + 2) So x = 0, x = – 1 or x = – 2Find the value of y when x = 0. Check what happens to y for large positive and negative values of x. The x3 term in the expanded function would be x Γ— (–x) Γ— x = –x3 so the curve has a negative x3 coefficient. Put y = 0 and solve for x. Explore the graph of y = (x – p )(x – q )(x – r ) where p , q and r are constants using GeoGebra.Online Put y = 0 and solve for x.
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61Graphs and transformations So the curve crosses the x -axis at (0, 0), ( βˆ’1, 0) and ( βˆ’2, 0). x β†’ ∞ , y β†’ ∞ x β†’ βˆ’βˆž, y β†’ βˆ’ ∞ –1 1 –2O xyYou know that the curve crosses the x-axis at (0, 0) so you don’t need to calculate the y-intercept separately. Check what happens to y for large positive and negative values of x. Example 2 Sketch the following curves. a y = (x βˆ’ 1)2(x + 1) b y = x3 βˆ’ 2x2 βˆ’ 3x c y = (x βˆ’ 2)3 a y = (x βˆ’ 1)2(x + 1) 0 = ( x βˆ’ 1)2(x + 1) So x = 1 or x = βˆ’ 1 So the curve crosses the x -axis at ( –1, 0) and touches the x -axis at (1, 0). When x = 0, y = ( βˆ’1)2 Γ— 1 = 1 So the curve crosses the y -axis at (0, 1). x β†’ ∞ , y β†’ ∞ x β†’ βˆ’βˆž, y β†’ βˆ’ ∞ y x O –1 11 b y = x3 βˆ’ 2x3 βˆ’ 3 x = x(x2 βˆ’ 2x βˆ’ 3) = x(x βˆ’ 3)( x + 1) 0 = x(x βˆ’ 3)( x + 1) So x = 0, x = 3 or x = βˆ’ 1 So the curve crosses the x -axis at (0, 0), (3, 0) and ( βˆ’1, 0). x β†’ ∞ , y β†’ ∞ x β†’ βˆ’βˆž, y β†’ βˆ’ ∞ y x O –1 3Put y = 0 and solve for x. (x – 1) is squared so x = 1 is a β€˜double’ repeated root. This means that the curve just touches the x-axis at (1, 0). Find the value of y when x = 0. Check what happens to y for large positive and negative values of x. This is a cubic curve with a positive coefficient of x 3 and three distinct roots.The x3 term in the expanded function would be x Γ— x Γ— x = x3 so the curve has a positive x3 coefficient. Check what happens to y for large positive and negative values of x. x β†’ ∞, y β†’ ∞ x = 1 is a β€˜double’ repeated root. x β†’ βˆ’βˆž, y β†’ βˆ’βˆž First factorise.
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62 Chapter 4 Example 3 Sketch the curve with equation y = (x – 1)(x2 + x + 2). y = ( x – 1)( x2 + x + 2) 0 = ( x – 1)( x2 + x + 2) So x = 1 only and the curve crosses the x-axis at (1, 0). When x = 0, y = ( –1)(2) = – 2 So the curve crosses the y -axis at (0, – 2). x β†’ ∞ , y β†’ ∞ x β†’ βˆ’βˆž, y β†’ βˆ’ ∞ y x O –21The quadratic factor x2 + x + 2 gives no solutions since the discriminant b2 – 4ac = (1)2 – 4(1)(2) = –7. ← Section 2.5 A cubi c graph could intersect the x-axis at 1, 2 or 3 points. Watch out Check what happens to y for large positive and negative values of x. You haven’t got enough information y x to know the exact shape of the graph. It could also be shaped like this: 1 Sketch the following curves and indicate clearly the points of intersection with the axes: a y = (x – 3)(x – 2)(x + 1) b y = (x – 1)(x + 2)(x + 3) c y = (x + 1)(x + 2)(x + 3) d y = (x + 1)(1 – x)(x + 3) e y = (x – 2)(x – 3)(4 – x) f y = x(x – 2)(x + 1) g y = x(x + 1)(x – 1) h y = x(x + 1)(1 – x) i y = (x – 2)(2x – 1)(2x + 1) j y = x(2x – 1)(x + 3)Exercise 4Ac y = (x – 2)3 0 = ( x – 2)3 So x = 2 and the curve crosses the x -axis at (2, 0) only. When x = 0, y = ( βˆ’2)3 = βˆ’8 So the curve crosses the y -axis at (0, – 8). x β†’ ∞ , y β†’ ∞ x β†’ βˆ’βˆž, y β†’ βˆ’ ∞ y x O –82Check what happens to y for large positive and negative values of x. x = 2 is a β€˜triple’ repeated root.
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63Graphs and transformations 2 Sketch the curves with the f ollowing equations: a y = (x + 1)2(x – 1) b y = (x + 2)(x – 1)2 c y = (2 – x)(x + 1)2 d y = (x – 2)(x + 1)2 e y = x2(x + 2) f y = (x – 1)2x g y = (1 – x)2(3 + x) h y = (x – 1)2(3 – x) i y = x2(2 – x) j y = x2(x – 2) 3 Factorise the follo wing equations and then sketch the curves: a y = x3 + x2 – 2x b y = x3 + 5x2 + 4x c y = x3 + 2x2 + x d y = 3x + 2x2 – x3 e y = x3 – x2 f y = x – x3 g y = 12x3 – 3x h y = x3 – x2 – 2x i y = x3 – 9x j y = x3 – 9x2 4 Sketch the following curves and indicate the coordinates of the points where the curves cross the axes: a y = (x – 2)3 b y = (2 – x)3 c y = (x – 1)3 d y = (x + 2)3 e y = –(x + 2)3 f y = (x + 3)3 g y = (x – 3)3 h y = (1 – x)3 i y = – (x – 2)3 j y = – (x – 1 _ 2 ) 3 5 The graph of y = x3 + bx2 + cx + d is shown opposite, where b, c and d y 1 –2–3 O x –6 are real constants. a Find the values of b, c and d. (3 marks) b Write down the coor dinates of the point where the curve crosses the y-axis. (1 mark) 6 The graph of y = ax3 + bx2 + cx + d is shown opposite, where a, b, c and d y x –12 3 O2 are real constants. Find the values of a, b, c and d. (4 marks) 7 Given tha t f(x) = (x – 10)(x2 – 2x) + 12x a Express f(x ) in the form x(ax2 + bx + c) where a, b and c are real constants. (3 marks) b Hence factorise f(x) complete ly. (2 marks) c Sketch the gra ph of y = f(x) showing clearly the points where the graph intersects the axes. (3 marks)P Start by writing the equation in the form y = (x – p)(x – q)(x – r).Problem-solving P E
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64 Chapter 4 Example 4 Sketch the following curves: a y = (x + 1)(x + 2)(x – 1)(x – 2) b y = x(x + 2)2(3 – x) c y = (x – 1)2(x – 3)2 a y = (x + 1)( x + 2)( x – 1)( x – 2) 0 = ( x + 1)( x + 2)( x – 1)( x – 2) So x = βˆ’ 1, βˆ’2, 1 or 2 The curve cuts the x -axis at ( –2, 0), ( –1, 0), (1, 0) and (2, 0). When x = 0, y = 1 Γ— 2 Γ— ( –1) Γ— (–2) = 4. So the curve cuts the y -axis at (0, 4). x β†’ ∞ , y β†’ ∞ x β†’ βˆ’βˆž, y β†’ ∞ Oy x21/four.ss01 –1–2We know the general shape of the quartic graph so we can draw a smooth curve through the points.4.2 Quartic graphs A quartic function has the form f(x) = ax4 + bx3 + cx2 + dx + e, where a, b, c, d and e are real numbers and a is non-zero. The graph of a quartic function can take several different forms, depending on the exact nature of the function. y xy xy x You can sketch the graph of a quartic function by finding the roots of the function.This is a repeated root. These roots are distinct. For this function a is negative.For these two functions a is positive. Check what happens to y for large positive and negative values of x.Substitute x = 0 into the function to find the coordinates of the y-intercept.Set y = 0 and solve to find the roots of the function. Explore the graph of y = (x – p )(x – q )(x – r )(x – s ) where p , q, r and s are constants using GeoGebra.Online
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65Graphs and transformations b y = x(x + 2)2(3 – x ) 0 = x(x + 2)2(3 – x ) So x = 0, – 2 or 3 The curve cuts the x -axis at (0, 0), ( –2, 0) and (3, 0) x β†’ ∞ , y β†’ βˆ’ ∞ x β†’ βˆ’βˆž, y β†’ βˆ’ ∞ Oy x –2 3 c y = (x – 1)2(x – 3)2 0 = ( x – 1)2(x – 3)2 So x = 1 or 3 The curve touches the x -axis at (1, 0) and (3, 0). When x = 0, y = 9.So the curve cuts the y -axis at (0, 9). x β†’ ∞ , y β†’ ∞ x β†’ βˆ’βˆž, y β†’ ∞ Oy x9 13The coefficient of x4 in the expanded function will be negative so you know the general shape of the curve. These are both β€˜double’ repeated roots, so the curve will just touch the x-axis at these points. The coefficient of x4 in the expanded function will be positive. There are two β€˜double’ repeated roots. 1 Sketch the following curves and indicate clearly the points of intersection with the axes: a y = (x + 1)(x + 2)(x + 3)(x + 4) b y = x(x – 1)(x + 3)(x – 2) c y = x(x + 1)2(x + 2) d y = (2x – 1)(x + 2)(x – 1)(x – 2) e y = x2(4x + 1)(4x – 1) f y = –(x – 4)2(x – 2)2 g y = (x – 3)2(x + 1)2 h y = (x + 2)3(x – 3) i y = –(2x – 1)3(x + 5) j y = (x + 4)4 2 Sketch the following curves and indicate clearly the points of intersection with the axes:a y = (x + 2)(x – 1)(x2 – 3x + 2) b y = (x + 3)2(x2 – 5x + 6) c y = (x – 4)2(x2 – 11x + 30) d y = (x2 – 4x – 32)(x2 + 5x – 36) In part f the coefficient of x4 will be negative.Hint Factorise the qu adratic factor first.HintExercise 4BThere is a β€˜double’ repeated root at x = βˆ’2 so the graph just touches the x-axis at this point.
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66 Chapter 4 3 The graph of y = x 4 + bx3 + cx2 + dx + e is shown opposite, where b, c, d and e are real constants. a Find the coordinates of point P. (2 marks) b Find the values of b, c, d and e. (3 marks) 4 Sketch the gra ph of y = (x + 5)(x – 4)(x2 + 5x + 14). (3 marks)E/P OPy x32 –2–1 E/P Consider the discriminant of the quadratic factor.Problem-solving 4.3 Reciprocal graphs You can sketch graphs of reciprocal functions such as y = 1 __ x , y = 1 __ x2 and y = βˆ’ 2 __ x by considering their as ymptotes. β–  The graphs of y = k __ x and y = k ___ x2 , where k is a real constant, have asymptotes at x = 0 and y = 0. An asy mptote is a line which the graph approaches but never reaches.Notation Oy x Oy x Oy x Oy x1 xy =–2 xy =2 x2y =–5 x2y = y = k __ x with k > 0. y = k __ x with k < 0. y = k __ x2 with k > 0. y = k __ x2 with k < 0.The graph of y = ax 4 + bx3 + cx2 + dx + e is shown, where a, b, c, d and e are real constants. Find the values of a, b, c, d and e. Oy x 3 –13Challenge
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67Graphs and transformations Example 5 Sketch on the same diagram: a y = 4 __ x and y = 12 ___ x b y = – 1 __ x and y = – 3 __ x c y = 4 __ x2 and y = 10 ___ x2 a O12 xy = 12 xy =/four.ss01 xy = /four.ss01 xy =xy b c 10 x2 y =10 x2 y = /four.ss01 x2 y =/four.ss01 x2 y = x Oy1 xy = –1 xy = – 3 xy = –3 xy = – x OyThis is a y = k __ x graph with k > 0 In this quadrant, x > 0 so for any values of x: 12 ___ x > 4 __ x In this quadrant, x < 0 so for any values of x: 12 ___ x < 4 __ x This is a y = k __ x graph with k < 0 In this quadrant, x < 0 so for any values of x: βˆ’ 3 __ x > βˆ’ 1 __ x In this quadrant, x > 0 so for any values of x: βˆ’ 3 __ x < βˆ’ 1 __ x This is a y = k __ x2 graph with k > 0. x2 is always positive and k > 0 so the y-values are all positive. 1 Use a separate dia gram to sketch each pair of graphs. a y = 2 __ x and y = 4 __ x b y = 2 __ x and y = βˆ’ 2 __ x c y = βˆ’ 4 __ x and y = βˆ’ 2 __ x d y = 3 __ x and y = 8 __ x e y = βˆ’ 3 __ x and y = βˆ’ 8 __ x 2 Use a separate dia gram to sketch each pair of graphs. a y = 2 __ x2 and y = 5 __ x2 b y = 3 __ x2 and y = βˆ’ 3 __ x2 c y = βˆ’ 2 __ x2 and y = βˆ’ 6 __ x2 Exercise 4C Explore the graph of y = a __ x for different values of a in GeoGebra.Online
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68 Chapter 4 4.4 Points of intersection You can sketch curves of functions to show points of intersection and solutions to equations. β–  The x-coordinate(s) at the points of intersection of the curves with equations y = f(x) and y = g(x) are the solution(s) to the equation f( x) = g( x). a y x CBA 1 3Oy = x(x – 3) y = x2(1 – x) b From the graph there are three points wh ere the curves cross, labelled A, B and C. The x -coordinates are given by the solutions to the equation. x(x βˆ’ 3) = x2(1 βˆ’ x) x2 βˆ’ 3 x = x2 βˆ’ x3 x3 βˆ’ 3 x = 0 x(x2 βˆ’ 3) = 0 So x = 0 or x2 = 3 So x = βˆ’ βˆšβ€―__ 3 , 0, βˆšβ€―__ 3 Sub stitute into y = x2 (1 βˆ’ x) T he points of intersection are: A(βˆ’ βˆšβ€―__ 3 , 3 + 3 βˆšβ€―__ 3 ) B(0 , 0) C( βˆšβ€―__ 3 , 3 βˆ’ 3 βˆšβ€―__ 3 )A cubic curve will eventually get steeper than a quadratic curve, so the graphs will intersect for some negative value of x. There are three points of intersection so the equation x(x – 3) = x 2(1 – x) has three real roots. Multiply out brackets.Collect terms on one side.Factorise. The graphs intersect for these values of x, so you can substitute into either equation to find the y-coordinates. Leave your answers in surd form.Example 6 a On the same diagram sk etch the curves with equations y = x(x βˆ’ 3) and y = x2 (1 βˆ’ x ). b Find the coordinates of the points of intersection. Example 7 a On the same diagram sk etch the curves with equations y = x2(3x βˆ’ a) and y = b __ x , where a and b are positive constants. b State, gi ving a reason, the number of real solutions to the equation x2(3x βˆ’ a) βˆ’ b __ x = 0
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69Graphs and transformations a y x Oy = x2(3x – a) ab xy =b x 1 3y = b From the sketch there are only two points of i ntersection of the curves. This means there are only two values of x where x2 (3x βˆ’ a) = b __ x or x2 (3x βˆ’ a) – b __ x = 0 So this equation has two real solutions.You can sketch curves involving unknown constants. You should give any points of intersection with the coordinate axes in terms of the constants where appropriate.Problem-solving Example 8 a Sketch the curves y = 4 ___ x 2 and y = x 2(x – 3) on the same axes. b Using your sketch, sta te, with a reason, the number of real solutions to the equation x 4(x βˆ’ 3) βˆ’ 4 = 0. a y x y = x2(x – 3)/four.ss01 x2y = O 3 b There is a single point of intersection so the equation x2(x βˆ’ 3) = 4 ___ x2 has one real solution . Rearranging: x 4(x βˆ’ 3) = 4 x 4(x βˆ’ 3) βˆ’ 4 = 0 So this equation has one real solution.Set the functions equal to each other to form an equation with one real solution, then rearrange the equation into the form given in the question.Problem-solving You would not be expected to solve this equation in your exam. 1 In each case: i sketch the two curv es on the same axes ii state the number of points of intersection iii write down a suitab le equation which would give the x-coordinates of these points. (Y ou are not required to solve this equation.)Exercise 4D3x – a = 0 when x = 1 __ 3 a, so the graph of y = x2(3x – a) touches the x-axis at (0, 0) and intersects it at ( 1 __ 3 a, 0) You only need to state the number of solutions. You don’t need to find the solutions.
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70 Chapter 4 a y = x2, y = x(x2 βˆ’ 1) b y = x(x + 2), y = βˆ’ 3 __ x c y = x2, y = (x + 1)(x βˆ’ 1)2 d y = x2(1 βˆ’ x), y = βˆ’ 2 __ x e y = x(x βˆ’ 4), y = 1 __ x f y = x(x βˆ’ 4), y = βˆ’ 1 __ x g y = x(x βˆ’ 4), y = (x βˆ’ 2)3 h y = βˆ’x3, y = βˆ’ 2 __ x i y = βˆ’x3, y = x2 j y = – x3, y = βˆ’x(x + 2) k y = 4, y = x(x βˆ’ 1)(x + 2)2 l y = x3, y = x2(x + 1)2 2 a On the same axes sketch the curv es given by y = x2(x βˆ’ 3) and y = 2 __ x b Explain how your sk etch shows that there are only two real solutions to the equation x 3(x βˆ’ 3) = 2. 3 a On the same axes sketch the curv es given by y = (x + 1)3 and y = 3x(x βˆ’ 1). b Explain how your sk etch shows that there is only one real solution to the equation x 3 + 6x + 1 = 0. 4 a On the same axes sketch the curv es given by y = 1 __ x and y = βˆ’x(x βˆ’ 1)2. b Explain how your sk etch shows that there are no real solutions to the equation 1 + x2(x βˆ’ 1)2 = 0. 5 a On the same axes sketch the curv es given by y = x2(x + a) and y = b __ x where a and b are both positive constants. (5 marks) b Using your sketch, sta te, giving a reason, the number of real solutions to the equation x 4 + ax3 – b = 0. (1 mark) 6 a On the same set of axes sk etch the graphs of y = 4 __ x2 and y = 3x + 7. (3 marks) b Write down the n umber of real solutions to the equation 4 __ x2 = 3x + 7. (1 mark) c Show that y ou can rearrange the equation to give (x + 1)(x + 2)(3x – 2) = 0. (2 marks) d Hence determine the exact coor dinates of the points of intersection. (3 marks) 7 a On the same axes sketch the curv e y = x3 – 3x2 – 4x and the line y = 6x. b Find the coordinates of the points of intersection. 8 a On the same axes sketch the curv e y = (x2 – 1)(x – 2) and the line y = 14x + 2. b Find the coordinates of the points of intersection. 9 a On the same axes sketch the curv es with equations y = (x – 2)(x + 2)2 and y = –x2 – 8. b Find the coordinates of the points of intersection. 10 a Sketch the gra phs of y = x2 + 1 and 2y = x – 1. (3 marks) b Explain why ther e are no real solutions to the equation 2x2 – x + 3 = 0. (2 marks) c Work out the r ange of values of a such that the graphs of y = x2 + a and 2y = x – 1 have two points of intersection. (5 marks)E/P Even though you don’t know the values of a and b , you know they are positive, so you know the shapes of the graphs. You can label the point a on the x -axis on your sketch of y = x2(x + a).Problem-solving E P P E/P
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71Graphs and transformations 11 a Sketch the gra phs of y = x2(x – 1)(x + 1) and y = 1 _ 3 x3 + 1. (5 marks) b Find the number of r eal solutions to the equation 3x2(x – 1)(x + 1) = x3 + 3. (1 mark)E/P 4.5 Translating graphs You can transform the graph of a function by altering the function. Adding or subtracting a constant β€˜outside’ the function translates a graph vertically. β–  The graph of y = f(x) + a is a translation of the graph y = f(x) by the vector ( 0 a ) . Adding or subtracting a constant β€˜inside’ the function translates the graph horizontally. β–  The graph of y = f(x + a) is a translation of the graph y = f(x) by the vector ( βˆ’a 0 ) . y x O2 4 1 3 –2 –4–5 –1 –3123456 –1y = f(x + 2) is a translation ( –2 0 ) , or 2 units in the direction of the negative x-axis.y = f(x) + 1 is a translation ( 0 1 ) , or 1 unit in the direction of the positive y-axis. Example 9 Sketch the graphs of: a y = x2 b y = (x βˆ’ 2)2 c y = x2 + 2 a y x O b y y = (x – 2)2 x/four.ss01 2 OThis is a translation by vector ( 2 0 ) . Remember to mark on the intersections with the axes.
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72 Chapter 4 c y = x2 + 2 y x2 OThis is a translation by vector ( 0 2 ) . Remember to mark on the y-axis intersection. Example 10 f(x) = x3 g(x) = x(x – 2) Sketch the following graphs, indicating any points where the curves cross the axes:a y = f(x + 1) b y = g(x + 1) a The graph of f( x) is y x Oy = f( x) = x3 So the graph of y = f( x + 1) is y x Oy = f( x + 1) = ( x + 1)3 –11 b g(x) = x(x βˆ’ 2) The curve is y = x (x βˆ’ 2) 0 = x(x βˆ’ 2) So x = 0 or x = 2 y xy = g( x) = x(x – 2) 2 OFirst sketch y = f(x). This is a translation of the graph of y = f(x) by vector ( βˆ’1 0 ) . You could also write out the equation as y = (x + 1)3 and sketch the graph directly. First sketch g(x).Put y = 0 to find where the curve crosses the x-axis. Explore translations of the gr aph of y = x3 using GeoGebra.Online
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73Graphs and transformations So the graph of y = g( x + 1) is y xy = g( x + 1) = (x + 1)( x – 1) 1 –1–1O β–  When you translate a function, any asymptotes are also translated. Example 11 Given that h(x) = 1 __ x , sketch the curve with equation y = h(x) + 1 and state the equations of any asymptotes and intersections with the axes . The graph of y = h( x) is Oy x1 xy = So the graph of y = h( x) + 1 is Oy x1 The curve crosses the x -axis once. y = h(x) + 1 = 1 __ x + 1 0 = 1 __ x + 1 βˆ’1 = 1 __ x x = βˆ’1 So t he curve intersects the x -axis at (βˆ’1, 0). The horizontal asymptote is y = 1. The vertical asymptote is x = 0.First sketch y = h(x ). The curve is translated by vector ( 0 1 ) so the asymptote is translated by the same vector. Put y = 0 to find where the curve crosses the x-axis. Remember to write down the equation of the vertical asymptote as well. It is the y-axis so it has equation x = 0.This is a translation of the graph of y = g(x) by vector ( βˆ’1 0 ) . You could also write out the equation and sketch the graph directly: y = g(x + 1) = (x + 1)(x + 1 – 2) = (x + 1)(x – 1)
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74 Chapter 4 1 Apply the f ollowing transformations to the curves with equations y = f(x) where: i f(x ) = x2 ii f(x) = x3 iii f(x) = 1 __ x In each case state the coordina tes of points where the curves cross the axes and in iii state the equations of the asymptotes. a f(x + 2) b f(x) + 2 c f(x βˆ’ 1) d f(x) βˆ’ 1 e f(x ) βˆ’ 3 f f(x βˆ’ 3) 2 a Sketch the curve y = f(x) where f(x) = (x βˆ’ 1)(x + 2). b On separate dia grams sketch the graphs of i y = f(x + 2) ii y = f(x) + 2. c Find the equations of the curv es y = f(x + 2) and y = f(x) + 2, in terms of x, and use these equations to find the coordinates of the points where your graphs in part b cross the y-axis. 3 a Sketch the gra ph of y = f(x) where f(x) = x2(1 βˆ’ x). b Sketch the curve with equa tion y = f(x + 1). c By finding the equation f(x + 1) in terms of x, find the coordinates of the point in part b where the curve crosses the y-axis. 4 a Sketch the gra ph of y = f(x) where f(x) = x(x βˆ’ 2)2. b Sketch the curves with equa tions y = f(x) + 2 and y = f(x + 2). c Find the coordinates of the points where the graph of y = f(x + 2) crosses the axes. 5 a Sketch the gra ph of y = f(x) where f(x) = x(x βˆ’ 4). b Sketch the curves with equa tions y = f(x + 2) and y = f(x) + 4. c Find the equations of the curv es in part b in terms of x and hence find the coordinates of the points where the curves cross the axes. 6 a Sketch the gra ph of y = f(x) where f(x) = x2(x – 1)(x – 2). b Sketch the curves with equa tions y = f(x + 2) and y = f(x) – 1. 7 The point P(4, –1) lies on the curve with equation y = f(x). a State the coordina tes that point P is transformed to on the curve with equation y = f(x – 2). (1 mark) b State the coordina tes that point P is transformed to on the curve with equation y = f(x) + 3. (1 mark) 8 The graph of y = f(x) where f(x) = 1 __ x is translated so that the asymptotes are at x = 4 and y = 0. Write down the equation for the transformed function in the form y = 1 _____ x + a (3 marks) 9 a Sketch the gra ph of y = x3 – 5x2 + 6x, marking clearly the points of intersection with the axes. b Hence sketch y = (x – 2)3 – 5(x – 2)2 + 6(x – 2). E E/P PExercise 4E
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75Graphs and transformations 10 a Sketch the gra ph of y = x2(x – 3)(x + 2), marking clearly the points of intersection with the axes. b Hence sketch y = (x + 2)2(x – 1)(x + 4). 11 a Sketch the gra ph of y = x3 + 4x2 + 4x. (6 marks) b The point with coordinates ( –1, 0) lies on the curve with equation y = (x + a)3 + 4(x + a)2 + 4(x + a) where a is a constant. Find the two possible values of a. (3 marks) 12 a Sketch the gra ph of y = x(x + 1)(x + 3)2. (4 marks) b Find the possible va lues of b such that the point (2, 0) lies on the curve with equation y = (x + b)(x + b + 1)(x + b + 3)2. (3 marks)P E/P E/P 1 Sketch the graph of y = (x – 3)3 + 2 and determine the coordinates of the point of inflection. β†’ Section 12.9 2 The point Q (–5, –7) lies on the curve with equation y = f( x). a Sta te the coordinates that point Q is transformed to on the curve with equation y = f( x + 2) – 5. b The c oordinates of the point Q on a transformed curve are ( –3, –6). Write down the transformation in the form y = f( x + a) – b.ChallengeLook at your sketch and picture the curve sliding to the left or right.Problem-solving 4.6 Stretching graphs Multiplying by a constant β€˜outside’ the function stretches the graph vertically. β–  The graph of y = af(x) is a stretch of the graph y = f(x) by a scale factor of a in the vertical direction. Oy x –11y = f(x)1 2y = 2f(x)y = f(x) Multiplying by a constant β€˜inside’ the function stretches the graph horizontally. β–  The graph of y = f(ax) is a stretch of the graph y = f(x) by a scale factor of 1 __ a in the horizontal direction. Oy x 2 64 y = f( x)1 3y = f(2x) y = f(x)2f(x) is a stretch with scale factor 2 in the y-direction. All y-coordinates are doubled. 1 _ 2 f(x) is a stretch with scale factor 1 _ 2 in the y-direction. All y-coordinates are halved. y = f ( 1 _ 3 x) is a stretch with scale factor 3 in the x-direction. All x-coordinates are tripled.y = f(2x) is a stretch with scale factor 1 _ 2 in the x-direction. All x-coordinates are halved.
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76 Chapter 4 Example 12 Given that f(x) = 9 βˆ’ x2, sketch the curves with equations: a y = f(2x) b y = 2f(x) a f(x) = 9 βˆ’ x2 So f(x) = (3 βˆ’ x)(3 + x ) The curve is y = (3 βˆ’ x )(3 + x ) 0 = (3 βˆ’ x )(3 + x ) So x = 3 or x = βˆ’ 3 So the curve crosses the x -axis at (3, 0) and (βˆ’3, 0). When x = 0, y = 3 Γ— 3 = 9 So the curve crosses the y -axis at (0, 9). The curve y = f( x) is 3 –39 O xy y = f(2 x) so the curve is 1.5 –1.59 O xy b y = 2f(x) so the curve is 3 –3/one.ss018 x OyYou can factorise the expression. Put y = 0 to find where the curve crosses the x-axis. Put x = 0 to find where the curve crosses the y-axis. First sketch y = f(x). y = f(ax) where a = 2 so it is a horizontal stretch with scale factor 1 _ 2 . Check: The curve is y = f(2x). So y = (3 βˆ’ 2x)(3 + 2x). When y = 0, x = βˆ’1.5 or x = 1.5.So the curve crosses the x-axis at (βˆ’1.5, 0) and (1.5, 0).When x = 0, y = 9.So the curve crosses the y-axis at (0, 9). y = af(x) where a = 2 so it is a vertical stretch with scale factor 2. Check: The curve is y = 2f(x). So y = 2(3 βˆ’ x)(3 + x).When y = 0, x = 3 or x = βˆ’3.So the curve crosses the x -axis at (βˆ’ 3, 0) and (3, 0). When x = 0, y = 2 Γ— 9 = 18.So the curve crosses the y-axis at (0, 18).
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77Graphs and transformations Example 13 a Sketch the curve with equation y = x(x – 2)(x + 1). b On the same axes, sk etch the curves y = 2x(2x – 2)(2x + 1) and y = βˆ’x(x – 2)(x + 1). a Oy x 2y = x(x – 2)( x + 1) –1 b y = x(x – 2)( x + 1)y = 2 x(2x – 2)(2 x + 1)y = –x(x – 2)( x + 1) Oy x 2 –1y = –x(x – 2)(x + 1) is a stretch with scale factor –1 in the y-direction. Notice that this stretch has the effect of reflecting the curve in the x-axis. y = 2x(2x – 2)(2x + 1) is a stretch with scale factor 1 _ 2 in the x-dir ection. You need to work out the relationship between each new function and the original function. If x(x – 2)(x + 1) = f( x) then 2x(2x – 2)(2 x + 1) = f(2 x), and –x(x – 2)(x + 1) = – f(x).Problem-solving β–  The graph of y = –f(x) is a reflection of the graph of y = f(x) in the x-axis. β–  The graph of y = f(– x) is a reflection of the graph of y = f(x) in the y-axis. Example 14 On the same axes sketch the graphs of y = f(x), y = f(βˆ’x) and y = βˆ’f(x) where f(x) = x(x + 2). f(x) = x(x + 2) y x O 2 –2 y = –f(x)y = f( x) y = f(–x)y = f(βˆ’x) is y = (βˆ’x)(βˆ’x + 2) which is y = x2 βˆ’ 2x or y = x(x βˆ’ 2) and this is a reflection of the original curve in the y-axis. Alternatively multiply each x-coordinate by βˆ’1 and leave the y-coordinates unchanged. This is the same as a stretch parallel to the x-axis scale factor βˆ’1. y = βˆ’f(x) is y = βˆ’x(x + 2) and this is a reflection of the original curve in the x-axis. Alternatively multiply each y-coordinate by βˆ’1 and leave the x-coordinates unchanged. This is the same as a stretch parallel to the y-axis scale factor βˆ’1. Explore stretches of the graph of y = x (x – 2)( x + 1) using GeoGebra.Online
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78 Chapter 4 1 Apply the f ollowing transformations to the curves with equations y = f(x) where: i f(x ) = x2 ii f(x) = x3 iii f(x) = 1 __ x In each case show both f(x ) and the transformation on the same diagram. a f(2x) b f(βˆ’x ) c f( 1 _ 2 x) d f(4x) e f( 1 _ 4 x) f 2f(x ) g βˆ’f(x ) h 4f(x ) i 1 _ 2 f(x) j 1 _ 4 f(x) 2 a Sketch the curv e with equation y = f(x) where f(x) = x2 βˆ’ 4. b Sketch the gra phs of y = f(4x), 1 _ 3 y = f(x), y = f(βˆ’x) and y = βˆ’f(x). 3 a Sketch the curv e with equation y = f(x) where f(x) = (x βˆ’ 2)(x + 2)x. b Sketch the gra phs of y = f( 1 _ 2 x), y = f(2x) and y = βˆ’f(x). 4 a Sketch the curv e with equation y = x2(x – 3). b On the same axes, sk etch the curves with equations: i y = (2x)2(2x – 3) ii y = βˆ’x2(x – 3) 5 a Sketch the curv e y = x2 + 3x – 4. b On the same axes, sk etch the graph of 5y = x2 + 3x – 4. 6 a Sketch the gr aph of y = x2(x – 2)2. b On the same axes, sk etch the graph of 3y = –x2(x – 2)2. 7 The point P(2, βˆ’3) lies on the curve with equation y = f(x). a State the coordina tes that point P is transformed to on the curve with equation y = f(2x). (1 mark) b State the coordina tes that point P is transformed to on the curve with equation y = 4f(x). (1 mark) 8 The point Q( βˆ’2, 8) lies on the curve with equation y = f(x). State the coor dina tes that point Q is transformed to on the curve with equation y = f( 1 _ 2 x). (1 mark) 9 a Sketch the gr aph of y = (x – 2)(x – 3)2. (4 marks) b The graph of y = (ax – 2)(ax – 3)2 passes through the point (1, 0). Find two possible values for a . (3 marks) For part b, rearrange the s econd equation into the form y = 3f( x).Hint P Let f( x) = x2(x – 3) and try to write each of the equations in part b in terms of f( x).Problem-solving E E E/PExercise 4F 1 The point R(4, βˆ’ 6) lies on the curve with equation y = f(x). State the coordinates that point R is transformed to on the curve with equation y = 1 _ 3 f(2x). 2 The p oint S(βˆ’4, 7) is transformed to a point S9(βˆ’8, 1.75). Write down the transformation in the form y = af(bx).Challenge
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79Graphs and transformations 4.7 Transforming functions You can apply transformations to unfamiliar functions by considering how specific points and features are transformed. Example 15 The following diagram shows a sketch of the curve f(x) which passes through the origin. The points A(1, 4) and B(3, 1) also lie on the curve. Sketch the following: a y = f(x + 1) b y = f(x βˆ’ 1) c y = f(x) βˆ’ 4 d 2y = f(x) e y βˆ’ 1 = f(x) In each case you should show the positions of the images of the points O, A and B.y x Oy = f(x) B (3, 1)A (1, 4) a f(x + 1) O(2, 1)/four.ss01 –1 xy y = f( x + 1) b f(x βˆ’ 1) O(/four.ss01, 1) 1(2, /four.ss01) xy y = f( x – 1) c f(x) βˆ’ 4 y x O –/four.ss011 (3, –3)y = f( x) – 4Translate f(x) 1 unit in the direction of the negative x-axis. Translate f(x) 1 unit in the direction of the positive x-axis. Translate f(x) 4 units in the direction of the negative y-axis.
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80 Chapter 4 d 2y = f(x) so y = 1 __ 2 f(x) (3, )(1, 2) 1 2y = f(x)1 2y x O e y βˆ’ 1 = f( x) so y = f( x) + 1 1y x O(3, 2)(1, 5) y = f( x) + 1Rearrange in the form y = … Stretch f(x) by scale factor 1 _ 2 in the y-dir ection. Rearrange in the form y = … Translate f(x) 1 unit in the direction of the positive y-axis. 1 The following diagram shows a sketch of the curve y x O(4, 4) C B DA2 1 6 with equation y = f(x). The points A(0, 2), B(1, 0), C(4, 4) and D(6, 0) lie on the curve. Sketch the following graphs and give the coordinates of the points, A, B, C and D after each transformation: a f(x + 1) b f(x ) βˆ’ 4 c f(x + 4) d f(2x ) e 3f(x ) f f( 1 _ 2 x) g 1 _ 2 f(x) h f(βˆ’ x) 2 The curve y = f(x) passes through the origin and y x Ox = 1y = 2 has horizontal asymptote y = 2 and vertical asymptote x = 1, as shown in the diagram. Sketch the following graphs. Give the equations of any asymptotes and give the coordinates of intersections with the axes after each transformation. a f(x ) + 2 b f(x + 1) c 2f(x ) d f(x ) βˆ’ 2 e f(2x ) f f( 1 _ 2 x) g 1 _ 2 f(x) h βˆ’f(x )Exercise 4G
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81Graphs and transformations 3 The curve with equation y = f(x) passes through the y x OB CD A (–4, –6)–2 4 –3 points A(βˆ’4, βˆ’6), B(βˆ’2, 0), C(0, βˆ’3) and D(4, 0) as shown in the diagram. Sketch the following and give the coordinates of the points A, B, C and D after each transformation. a f(x βˆ’ 2) b f(x ) + 6 c f(2x ) d f(x + 4) e f(x ) + 3 f 3f(x ) g 1 _ 3 f(x) h f( 1 _ 4 x) i βˆ’f(x ) j f(βˆ’ x) 4 A sketch of the curv e y = f(x) is shown in the y x Ox = –21 diagram. The curve has a vertical asymptote with equation x = βˆ’2 and a horizontal asymptote with equation y = 0. The curve crosses the y-axis at (0, 1). a Sketch, on separa te diagrams, the graphs of: i 2f(x ) ii f(2x ) iii f(x βˆ’ 2) iv f(x ) βˆ’ 1 v f(βˆ’ x) vi βˆ’f(x ) In each case state the equations of any asymptotes and, if possible, points where the curve cuts the axes. b Suggest a possible equation f or f(x). 5 The point P(2, 1) lies on the gr aph with equation y = f(x). a On the graph of y = f(ax), the point P is mapped to the point Q(4, 1). Determine the value of a. (1 mark) b Write down the coor dinates of the point to which P maps under each transformation i f(x – 4) ii 3f(x ) iii 1 _ 2 f(x) – 4 (3 marks) 6 The diagram sho ws a sketch of a curve with equation y = f(x). The points A(βˆ’1, 0), B(0, 2), C(1, 2) and D(2, 0) lie on the curve. Sketch the following graphs and give the coordinates of the points A, B, C and D after each transformation: a y + 2 = f(x) b 1 _ 2 y = f(x) c y βˆ’ 3 = f(x) d 3y = f(x) e 2y βˆ’ 1 = f(x)E/P OABC Dy xP Rearrange each equation into the form y = …Problem-solving
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82 Chapter 4 1 a On the same axes sketch the gr aphs of y = x2(x βˆ’ 2) and y = 2x βˆ’ x2. b By solving a suitable equa tion find the points of intersection of the two graphs. 2 a On the same axes sketch the curv es with equations y = 6 __ x and y = 1 + x. b The curves intersect at the points A and B . Find the coordinates of A and B . c The curve C with equa tion y = x2 + px + q, where p and q are integers, passes through A and B . Find the values of p and q . d Add C to y our sketch. 3 The diagram sho ws a sketch of the curve y = f(x). y x O2 BA (3, 4) y = 2 The point B (0, 0) lies on the curve and the point A (3, 4) is a maximum point. The line y = 2 is an asymptote. Sketch the following and in each case give the coordinates of the new positions of A and B and state the equation of the asymptote: a f(2x) b 1 _ 2 f(x) c f(x) βˆ’ 2 d f(x + 3) e f(x βˆ’ 3) f f(x) + 1 4 The diagram sho ws the curve with equation y = 5 + 2x βˆ’ x2 and the line with equation y = 2. The curve and the line intersect at the points A and B . Find the x -coordinates of A and B . (4 marks) 5 f(x ) = x2(x – 1)(x – 3). a Sketch the gra ph of y = f(x). (2 marks) b On the same axes, dr aw the line y = 2 – x. (2 marks) c State the number of real solutions to the equation x2(x – 1)(x – 3) = 2 – x. (1 mark) d Write down the coor dinates of the point where the graph with equation y = f(x) + 2 crosses the y-axis. (1 mark) 6 The figure shows a sk etch of the curve with equation y = f(x). On separate axes sketch the curves with equations:a y = f(– x) (2 marks) b y = –f(x) (2 marks) Mark on each sketch the x-coordinate of any point, or points, where the curve touches or crosses the x -axis.P Ey x Oy = 2 B A y = 5 + 2x – x2 E/P Ey x O –2 2Mixed exercise 4
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83Graphs and transformations 7 The diagram sho ws the graph of the quadratic function f(x). x O13 (2, –1)y y = f(x) The graph meets the x-axis at (1, 0) and (3, 0) and the minimum point is (2, βˆ’1). a Find the equation of the gr aph in the form y = ax2 + bx = c (2 marks) b On separate ax es, sketch the graphs of i y = f(x + 2) ii y = (2x). (2 marks) c On each graph la bel the coordinates of the points at which the graph meets the x-axis and label the coordinates of the minimum point. 8 f(x ) = (x βˆ’ 1)(x βˆ’ 2)(x + 1). a State the coordina tes of the point at which the graph y = f(x ) intersects the y -axis. (1 mark) b The graph of y = af(x) intersects the y -axis at (0, βˆ’ 4). Find the value of a . (1 mark) c The graph of y = f(x + b) passes through the origin. Find three possible values of b . (3 marks) 9 The point P(4, 3) lies on a curv e y = f(x). a State the coordina tes of the point to which P is transformed on the curve with equation: i y = f(3x) ii 1 _ 2 y = f(x) iii y = f(x βˆ’ 5) iv βˆ’y = f(x) v 2( y + 2) = f(x) b P is transf ormed to point (2, 3). Write down two possible transformations of f(x). c P is transf ormed to point (8, 6). Write down a possible transformation of f(x) if i f(x ) is translated only ii f(x ) is stretched only. 10 The curve C1 has equation y = βˆ’ a __ x2 where a is a positive constant. The curve C2 has the equation y = x2 (3x + b) where b is a positive constant. a Sketch C1 and C2 on the same set of axes, showing clearly the coordinates of any point where the curves touch or cross the axes. (4 marks) b Using your sketch sta te, giving reasons, the number of solutions to the equation x 4 (3x + b) + a = 0. (2 marks) 11 a Factorise completel y x3 βˆ’ 6x2 + 9x. (2 marks) b Sketch the curve of y = x3 βˆ’ 6x2 + 9x showing clearly the coordinates of the points where the curve touches or crosses the axes. (4 marks) c The point with coordinates ( βˆ’4, 0) lies on the curve with equation y = (x βˆ’ k)3 βˆ’ 6(x βˆ’ k)2 + 9(x βˆ’ k) where k is a constant. Find the two possible values of k. (3 marks) 12 f(x ) = x(x βˆ’ 2)2 Sketch on separate axes the graphs of: a y = f(x) (2 marks) b y = f(x + 3) (2 marks) Show on each sketch the coor dinates of the points where each graph crosses or meets the axes.E/P E/P P E/P E/P E
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84 Chapter 4 13 Given tha t f(x) = 1 __ x , x β‰  0, a Sketch the gra ph of y = f(x) – 2 and state the equations of the asymptotes. (3 marks) b Find the coordinates of the point where the curve y = f(x) – 2 cuts a coordinate axis. (2 marks) c Sketch the gra ph of y = f(x + 3). (2 marks) d State the equations of the asymptotes and the coordinates of the point where the curve cuts a coordinate axis. (2 marks)E The point R (6, – 4) l ies on the curve with equation y = f( x). State the coordinates that point R is transformed to on the curve with equation y = f( x + c ) – d .Challenge 1 If p is a r oot of the function f( x), then the graph of y = f(x) touches or crosses the x-axis at the point (p, 0). 2 The graphs of y = k __ x and y = k __ x2 , where k is a real constant, have asymptotes at x = 0 and y = 0. 3 The x-coordinate(s) at the points of intersection of the curves with equations y = f(x) and y = g(x) are the solution(s) to the equation f( x) = g( x). 4 The graph of y = f(x) + a is a translation of the graph y = f(x) by the vector ( 0 a ) . 5 The graph of y = f(x + a) is a translation of the graph y = f(x) by the vector ( –a 0 ) . 6 When you translat e a function, any asymptotes are also translated. 7 The graph of y = af(x) is a stretch of the graph y = f(x) by a scale factor of a in the vertical direction. 8 The graph of y = f(ax) is a stretch of the graph y = f( x) by a scale factor of 1 __ a in the horizontal direction. 9 The graph of y = –f( x) is a reflection of the graph of y = f(x) in the x-axis. 10 The graph of y = f(– x) is a reflection of the graph of y = f(x) in the y-axis.Summary of key points
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Review exercise 851 1 a Write down the value of 8 1 _ 3 . (1 mark) b Find the value of 8 βˆ’ 2 _ 3 . (2 marks) ← Section 1.4 2 a Find the value of 12 5 4 _ 3 . (2 marks) b Simplify 24x2 Γ· 18 x 4 _ 3 . (2 marks) ← Sections 1.1, 1.4 3 a Express βˆšβ€―___ 80 in the form a βˆšβ€―__ 5 , where a is an integer. (2 marks) b Express (4 βˆ’ βˆšβ€―__ 5 )2 in the form b + c βˆšβ€―__ 5 , where b and c are integers. (2 marks) ← Section 1.5 4 a Expand and simplify (4 + βˆšβ€―__ 3 )(4 βˆ’ βˆšβ€―__ 3 ). (2 marks) b Express 26 ______ 4 + βˆšβ€―__ 3 in the form a + b βˆšβ€―__ 3 , where a and b are integers. (3 marks) ← Sections 1.5, 1.6 5 Here are three numbers: 1 βˆ’ √ __ k , 2 + 5 √ __ k and 2 √ __ k Given tha t k is a positive integer, find: a the mean of the three n umbers. (2 marks) b the range of the thr ee numbers. (1 mark) ← Section 1.5 6 Given that y = 1 ___ 25 x 4 , express each of the following in the form kxn, where k and n are constants. a yβˆ’1 (1 mark) b 5 y 1 _ 2 (1 mark) ← Section 1.4E E E E/p E7 Find the area of this tr apezium in cm2. Give your answer in the form a + b √ __ 2 , where a and b are integers to be found. (4 marks) ← Section 1.5 (5 + 3 2) cm3 + 2 cm 2 2 cm 8 Given that p = 3 βˆ’ 2 √ __ 2 and q = 2 βˆ’ √ __ 2 , find the value of p + q _____ p βˆ’ q . Give y our answer in the form m + n √ __ 2 , where m and n are rational numbers to be found. (4 marks) ← Sections 1.5, 1.6 9 a Factorise the expression x 2 βˆ’ 10x +16. (1 mark) b Hence, or otherwise, solv e the equation 82y βˆ’ 10(8y) + 16 = 0. (2 marks) ← Sections 1.3, 2.1 10 x2 βˆ’ 8x βˆ’ 29 (x + a)2 + b, where a and b are constants. a Find the value of a and the value of b. (2 marks) b Hence, or otherwise, sho w that the roots of x2 βˆ’ 8x βˆ’ 29 = 0 are c Β± d βˆšβ€―__ 5 , where c and d are integers. (3 marks) ← Sections 2.1, 2.2E/p E E/p E
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86 Review exercise 1 11 The functions f and g are defined as f( x) = x(x βˆ’ 2) and g(x) = x + 5, x ∈ ℝ . Given tha t f(a) = g(a) and a > 0, find the value of a to three significant figures. (3 marks) ← Sections 2.1, 2.3 12 An athlete launches a shot put from shoulder height. The height of the shot put, in metr es, above the ground tΒ seconds after launch, can be modelled by the following function: h(t) = 1.7 + 10t βˆ’ 5t 2 t > 0 a Give the ph ysical meaning of the constant term 1.7 in the context of the model. b Use the model to calcula te how many seconds after launch the shot put hits the ground. c Rearrange h( t) into the form AΒ βˆ’Β B(tΒ βˆ’Β C)2 and give the values of the constants A, B and C. d Using your answ er to part c or otherwise, find the maximum height of the shot put, and the time at which this maximum height is reached. ← Section 2.6 13 Given that f(x) = x2 βˆ’ 6x + 18, x > 0, a express f( x) in the form (x βˆ’ a)2 + b, where a and b are integers. (2 marks) The curve C with equation y = f(x), x > 0, meets the y-axis at P and has a minimum point at Q. b Sketch the gra ph of C, showing the coordinates of P and Q. (3 marks) The line y = 41 meets C at the point R. c Find the x-coor dinate of R, giving your answer in the form p + q βˆšβ€―__ 2 , where p and q are integers. (2 marks) ← Sections 2.2, 2.4 14 The function h(x) = x2 + 2 √ __ 2 x + k has equal roots. a Find the value of k. (1 mark) b Sketch the gra ph of y = h(x), clearly labelling any intersections with the coordinate axes. (3 marks) ← Sections 1.5, 2.4, 2.5E/p p E/p E15 The function g(x) is defined as g( x) = x9 βˆ’ 7x6 βˆ’ 8x3, x ∈ ℝ . a Write g(x ) in the f orm x3(x3 + a)(x3 + b), where a and b are integers. (1 mark) b Hence find the three roots of g(x). (1 mark) ← Section 2.3 16 Given that x2 + 10x + 36 (x + a)2 + b, where a and b are constants, a find the value of a and the value of b. (2 marks) b Hence show that the equa tion x2 + 10x + 36 = 0 has no real roots. (2 marks) The equation x2 + 10x + k = 0 has equal roots.c Find the value of k. (2 marks) d For this va lue of k, sketch the graph of y = x2 + 10x + k, showing the coordinates of any points at which theΒ graph meets the coordinate axes. (3 marks) ← Sections 2.2, 2.4, 2.5 17 Given that x2 + 2x + 3 (x + a)2 + b, a find the value of the constants a and b (2 marks) b Sketch the gra ph of y = x2 + 2x + 3, indicating clearly the coordinates of any intersections with the coordinate axes. (3 marks) c Find the value of the discriminant of x2 + 2x + 3. Explain how the sign of the discriminant relates to your sketch in part b. (2 marks) The equation x2 + kx + 3 = 0, where k is a constant, has no real roots. d Find the set of possible v alues of k, giving your answer in surd form. (2 marks) ← Section 2.2, 2.4, 2.5E/p E/p E/p
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87 Review exercise 1 18 a By eliminating y from the equations: y = x βˆ’ 4, 2x2 βˆ’ xy = 8, show that x2 + 4x βˆ’ 8 = 0. (2 marks) b Hence, or otherwise, solv e the simultaneous equations: y = x βˆ’ 4,2x 2 βˆ’ xy = 8, giving your answers in the form a Β± b βˆšβ€―__ 3 , where a and b are integers. (4 marks) ← Section 3.2 19 Find the set of va lues of x for which: a 3(2x + 1) > 5 βˆ’ 2x, (2 marks) b 2x2 βˆ’ 7x + 3 > 0, (3 marks) c both 3(2 x + 1) > 5 βˆ’ 2x and 2x2 βˆ’ 7x + 3 > 0. (1 mark) ← Sections 3.4, 3.5 20 The functions p and q are defined as p(x ) = βˆ’2(x + 1) and q(x) = x2 βˆ’ 5x + 2, x ∈ ℝ . Show alge braically that there is no value of x for which p(x ) = q(x). (3 marks) ← Sections 2.3, 2.5 21 a Solve the simultaneous equations: y + 2x = 5 2x2 βˆ’ 3x βˆ’ y = 16. (5 marks) b Hence, or otherwise, find the set of values of x for which: 2x2 βˆ’ 3x βˆ’ 16 > 5 βˆ’ 2x. (2 marks) ← Sections 3.2, 3.5 22 The equation x2 + kx + (k + 3) = 0, where k is a constant, has different real roots. a Show that k2 βˆ’ 4k βˆ’ 12 > 0. (2 marks) b Find the set of possible v alues of k. (2 marks) ← Sections 2.5, 3.5 23 Find the set of va lues for which 6 _____ x + 5 < 2, x β‰  βˆ’5. (6 marks) ← Section 3.5E E E/p E E/p E24 The functions f and g are defined as f( x) = 9 βˆ’ x2 and g(x) = 14 βˆ’ 6x, x ∈ ℝ . a On the same set of axes , sketch the graphs of y = f(x) and y = g(x). Indicate clearly the coordinates of anyΒ points where the graphs intersect with each other or the coordinate axes. (5 marks) b On your sketch, shade the r egion that satisfies the inequalities y > 0 and f(x)Β >Β g(x). (1 mark) ← Sections 3.2, 3.3, 3.7 25 a Factorise completely x3 βˆ’ 4x. (1 mark) b Sketch the curve with equa tion y = x3 βˆ’ 4x, showing the coordinates of the points where the curve crosses the x-axis. (2 marks) c On a separate dia gram, sketch the curve with equation y = (x βˆ’ 1)3 βˆ’ 4(x βˆ’ 1) showing the coordinates of the pointsΒ where the curve crosses the x-axis. (2 marks) ← Sections 1.3, 4.1, 4.5 26 O P(3, –2)y x 2 4 The figure shows a sketch of the curve with equation y = f(x). The curve crosses the x-axis at the points (2, 0) and (4, 0). The minimum point on the curve is P(3, βˆ’2). In separate diagrams, sketch the curves with equation a y = βˆ’f(x) (2 marks) b y = f(2 x) (2 marks) On each diagram, gi ve the coordinates of the points at which the curve crosses the x-axis, and the coordinates of the image of P under the given transformation. ← Sections 4.6, 4.7E E/p E
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88 Review exercise 1 27 13 4 Oy x The figure shows a sketch of the curve with equation y = f(x). The curve passes through the points (0, 3) and (4, 0) and touches the x-axis at the point (1, 0). On separate diagrams, sketch the curves with equations a y = f( x + 1) (2 marks) b y = 2f(x) (2 marks) c y = f ( 1 _ 2 x) (2 marks) On each diagram, sho w clearly the coordinates of all the points where the curve meets the axes. ← Sections 4.5, 4.6, 4.7 28 Given that f(x) = 1 __ x , x β‰  0, a sketch the gra ph of y = f(x) + 3 and state the equations of the asymptotes (2 marks) b find the coordinates of the point where y = f(x) + 3 crosses a coordinate axis. (2 marks) ← Sections 4.3, 4.5 29 The quartic function t is defined as t(x ) = (x2 βˆ’ 5x + 2)(x2 βˆ’ 5x + 4), x ∈ ℝ . a Find the four roots of t(x), giving your answers to 3 significant figures where necessary. (3 marks) b Sketch the gra ph of y = t(x), showing clearly the coordinates of all the pointsΒ where the curve meets the axes. (2 marks) ← Sections 4.2, 2.1 30 The point (6, βˆ’8) lies on the gr aph of yΒ =Β f(x). State the coordinates of the point to which P is transformed on the graph with equation: a y = βˆ’f(x) (1 mark) b y = f(x βˆ’ 3) (1 mark) c 2y = f(x) (1 mark) ← Section 4.7E E E E31 The curve C1 has equation y = βˆ’ a __ x , where a is a positive constant. The curve C2 has equation y = (x βˆ’ b)2, where b is a positive constant.a Sketch C1 and C2 on the same set of axes. Label any points where either curve meets the coordinate axes, givingΒ your coordinates in terms of a and b. (4 marks) b Using your sketch, sta te the number of real solutions to the equation x(x βˆ’ 5) 2 = 7. (1 mark) ← Sections 4.3, 4.4 32 a Sketch the graph of y = 1 __ x 2 βˆ’ 4 , showing clearl y the coordinates of the points where the curve crosses the coordinate axes and stating theΒ equations of the asymptotes. (4 marks) b The curve with y = 1 _______ (x + k)2 βˆ’ 4 passes thr ough the origin. Find the two possible values of k. (2 marks) ← Sections 4.1, 4.5, 4.7E/p E/p 1 a Solve the equation x2Β βˆ’Β 10 xΒ +Β 9Β =Β 0 b Hen ce, or otherwise, solve the equation 3x βˆ’ 2(3x βˆ’ 10) = βˆ’ 1 ← Sections 1.1, 1.3, 2.1 2 A rectangle has an area of 6 cm2 and a perimeter of 8 βˆšβ€―__ 2 cm. Find the dimensions of the re ctangle, giving your answers as surds in their simplest form. ← Sections 1.5, 2.2 3 Show algebraically that the graphs of yΒ  = 3x3 + x2 βˆ’ x and y = 2 x(x βˆ’ 1)( x + 1) have only one point of intersection, and find the coordinates of this point. ← Section 3.3 4 The quartic function f( x) = (x2 + x – 20)( x2 + x – 2) has three roots in common with the function g(x) = f(x βˆ’ k), where k is a constant. Find the two possible values of k . ← Sections 4.2, 4.5, 4.7Challenge
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89 Straight line graphs After completing this unit you should be able to: ● Calculat e the gradient of a line joining a pair of points β†’ pages 90 – 91 ● Understand the link between the equation o f a line, and its gradient and intercept β†’ pages 91 – 93 ● Find the equation of a line given (i) the gr adient and one point on the line or (ii) two points on the line β†’ pages 93 – 95 ● Find the point of intersection f or a pair of straight lines β†’ pages 95 – 96 ● Know and use the rules for parallel and perpendicular gradients β†’ pages 97 – 100 ● Solve length and area problems on coordinate grids β†’ pages 100 – 103 ● Use straight line graphs to construct mathematical models β†’ pages 103 – 108Objectives 1 Find the point of intersection o f the following pairs of lines.a y = 4x + 7 and 3y = 2x βˆ’ 1 b y = 5x βˆ’ 1 and 3x + 7y = 11 c 2x βˆ’ 5y = βˆ’1 and 5x βˆ’ 7y = 14 ← GC SE Mathematics 2 Simplify each of the following: a βˆšβ€―___ 80 b βˆšβ€―____ 200 c βˆšβ€―____ 125 ← Sec tion 1.5 3 Make y the subject of each equation: a 6x + 3y βˆ’ 15 = 0 b 2x βˆ’ 5y βˆ’ 9 = 0 c 3x βˆ’ 7y + 12 = 0 ← GCSE MathematicsPrior knowledge check Straight line graphs are used in mathematical modelling. Economists use straight line graphs to model how the price and availability of a good affect the supply and demand. β†’Β ExerciseΒ 5HΒ Q95
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90 Chapter 5 y x O(x2, y2) (x1, y1)x2 – x 1y2 – y 15.1 y = mx + c You can find the gradient of a straight line joining two points by considering the vertical distance and the horizontal distance between the points. β–  The gradient m of a line joining the point with coordinates ( x 1 , y 1 ) to the point with coordinates ( x 2 , y 2 ) can be calculated using the f ormula m = y2 βˆ’ y1 ______ x2 βˆ’ x1 a βˆ’ (βˆ’5) ________ 4 βˆ’ 2 = βˆ’1 So a + 5 ______ 2 = βˆ’1 a + 5 = βˆ’ 2 a = βˆ’7Example 2 The line joining (2, βˆ’5) to (4, a) has gradient βˆ’1. Work out the value of a. Use m = y2 βˆ’ y1 ______ x2 βˆ’ x1 . Here m = βˆ’1, (x1, y1) = (2, βˆ’5) and (x2, y2) = (4, a).Example 1 Work out the gradient of the line joining (βˆ’2, 7) and (4, 5) y x O(–2, 7) (4, 5) m = 5 βˆ’ 7 _______ 4 βˆ’ (βˆ’2) = βˆ’ 2 __ 6 = βˆ’ 1 __ 3 Use m = y2 βˆ’ y1 ______ x2 βˆ’ x1 . Here (x1, y1) = (βˆ’2, 7) and (x2, y2) = (4, 5) 1 Work out the gradients of the lines joining these pairs of points: a (4, 2), (6, 3) b (βˆ’1, 3), (5, 4) c (βˆ’4, 5), (1, 2) d (2, βˆ’3), (6, 5) e (βˆ’3, 4), (7, βˆ’6) f (βˆ’ 12, 3), (βˆ’2, 8) g (βˆ’2, βˆ’4), (10, 2) h ( 1 _ 2 , 2), ( 3 _ 4 , 4) i ( 1 _ 4 , 1 _ 2 ), ( 1 _ 2 , 2 _ 3 ) j (βˆ’2.4, 9.6), (0, 0) k (1.3, βˆ’2.2), (8.8, βˆ’4.7) l (0, 5a), (10 a, 0) m (3b , βˆ’2b), (7b, 2b) n ( p, p2), (q, q2)Exercise 5A Explore the gradient fo rmula using GeoGebra.Online
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91Straight line graphs 2 The line joining (3, βˆ’5) to (6, a) has a gradient 4. Work out the value of a. 3 The line joining (5, b) to (8, 3) has gr adient βˆ’3. Work out the value of b. 4 The line joining (c, 4) to (7, 6) has gr adient 3 _ 4 . Work out the value of c. 5 The line joining (βˆ’1, 2 d ) to (1, 4) has gradient βˆ’ 1 _ 4 . Work out the value of d. 6 The line joining (βˆ’3, βˆ’2) to (2e, 5) has gradient 2. Work out the value of e. 7 The line joining (7, 2) to ( f, 3f ) has gradient 4. Wor k out the value of f. 8 The line joining (3, βˆ’4) to ( βˆ’g, 2g) has gradient βˆ’3. Work out the value of g. 9 Show that the points A(2, 3), B(4, 4) and C(10,7) can be joined by a straight line. 10 Show that the points A(βˆ’2a, 5a), B(0, 4a) and points C(6a, a) are collinear. (3 marks) ● The equation of a straight line can be writt en in the form y = mx + c, where m is the gradient and c is the y-intercept. ● The equation of a straight line can also be writt en in the form ax + by + c = 0, where a, b and c are integers.P E/P Poi nts are collinear if they all lie on the same straight line.NotationFind the gradient of the line joining the points A and B and the line joining the points A and C .Problem-solving y x Oy = mx + c cm 1 a Gradient = βˆ’3 a nd y-intercept = (0, 2). b y = 4 __ 3 x + 5 __ 3 Grad ient = 4 __ 3 and y -intercept = (0, 5 __ 3 ).Example 3 Write down the gradient and y-intercept of these lines: a y = βˆ’3 x + 2 b 4x βˆ’ 3y + 5 = 0 Use f ractions rather than decimals in coordinate geometry questions.Watch outRearrange the equation into the form y = mx + c. From this m = 4 _ 3 and c = 5 _ 3 Compare y = βˆ’3x + 2 with y = mx + c. From this, m = βˆ’3 and c = 2.
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