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Year 12 Hemel Hempstead School Introduction to A level Maths INDUCTION BOOKLET SUMMER 2016 Name............................ USEFUL RESOURCES Sources for further help are indicated throughout the booklet. You may also find the following useful once you start the course. Examsolutions.co.uk A useful website which not only offers tutorial on all A level topics but also past exam questions with model solutions. Make sure you choose the Edexcel specification. http://www.examsolutions.co.uk/maths-revision/syllabuses/Edexcel/period-1/specification.php Sci2.co.uk This website contains all past papers including Solomon press papers which are harder revision materials http://sci2.co.uk/maths.html MyMaths.co.uk Login: Hempstead Password: 1491625 This trusted old friend now has lessons and tests for all A level topics Waldomaths.com A great website with step by step guides for every topic on the A level paper. Make sure you choose the Edexcel specification. http://www.waldomaths.com/revisionasa2.jsp Solutions to Practice Test (BACK PAGE) 1. (a) 2x2 + 4x – 3 (b) a2 + 6a + 9 (c) 12x2 – 8x – 2x2 – 5x = 10x2 – 13x 2. (a) x (x – 7) (b) (y + 8) (y – 8) 3. (a) 4. (a) x 4 1 16 5. (a) x =0 or x = (b) 6 x y (c) (2x – 1) (y + 3) 3 (b) 1 (c) (c) 1 (b) x = -7 or x = 2 2 6. (a) x= -0.17157 or x = -5.82843 2 3 x (d) (3t – 1) (2t – 5) 7 (d) (d) x 5 3 1 25 1 2 (b) x = 5.28388 or x = -0.28388 (c) x = 5 or x = (c) x =0.21525 or x =-1.54858 7. (a) sub x =2 into equation 8. x =3 and y = 4 (b) x = 13 9. x = - 2 and y = 1 or x = -1 and y = 2 2 INTRODUCTION TO A LEVEL MATHS AT HHS Thank you for choosing to study Mathematics in the sixth form at The Hemel Hempstead School. You will sit two modules in Core Mathematics (C1 and C2) as well as Mechanics (M1). The Core 1, 2 and Mechanics exams will be sat in in May/June 2017. The Mathematics Department is committed to ensuring that you make good progress throughout your A level or AS course. In order that you make the best possible start to the course, we have prepared this booklet. It is vitally important that you spend time working through the questions in this booklet over the summer - you will need to have a good knowledge of these topics before you commence your course in September. You should have met all the topics before at GCSE. Work through the introduction to each chapter, making sure that you understand the examples. We expect the solutions to each exercise to be handed in on the first day of the course in September. Failure to do so will imply that you are not committed to the course and your place will be reconsidered. We will test you at the start of September to check how well you understand these topics. These GCSE topics form the foundations for A level Maths and if you do not pass this test, you may wish to consider the suitability of the course for you. A mock test is provided at the back of this booklet. We hope that you will use this introduction to give you a good start to your AS work and that it will help you enjoy and benefit from the course more. Mr M Laroussi KS5 Co-ordinator Section 1 Section 2 Section 3 Section 4 Section 5 Section 6 CONTENTS Removing brackets Exercise A Exercise B Factorising Exercise C Exercise D Indices Exercise E Exercise F Solving quadratic equations Exercise G Simultaneous equations Exercise H Solving inequalities Exercise I Exercise J page page 4 5 5 page 5 6 7 page 8 8 9/10 10 11 page 12 13 page 13 14 14 Section 1: REMOVING BRACKETS To remove a single bracket, we multiply every term in the bracket by the number or the expression on the outside: Examples 1) 3 (x + 2y) = 3x + 6y 2) -2(2x - 3) = (-2)(2x) + (-2)(-3) = -4x + 6 To expand two brackets, we must multiply everything in the first bracket by everything in the second bracket. We can do this in a variety of ways, including * the smiley face method * FOIL (Fronts Outers Inners Lasts) * using a grid. Examples: 1) (x + 1)(x + 2) = x(x + 2) + 1(x + 2) (x +1)(x + 2) = x2 + 2 + 2x + x = x2 + 3x +2 or or x 2 2) x x2 2x 1 x 2 (x +1)(x + 2) = x2 + 2x + x + 2 = x2 + 3x +2 (x - 2)(2x + 3) = x(2x + 3) - 2(2x +3) = 2x2 + 3x – 4x - 6 = 2x2 – x – 6 or (x - 2)(2x + 3) = 2x2 – 6 + 3x – 4x = 2x2 – x – 6 or 2x 3 x 2x2 3x -2 -4x -6 (2x +3)(x - 2) = 2x2 + 3x - 4x - 6 = 2x2 - x - 6 4 EXERCISE A Multiply out the following brackets and simplify. 1. 7(4x + 5) = 5. 5(2x - 1) – (3x - 4)= 2. -3(5x - 7) = 6. (x + 2)(x + 3)= 3. 5a – 4(3a - 1)= 7. (t - 5)(t - 2)= t2 -2t -5t +10 = 4. 4y + y(2 + 3y) = Two Special Cases Perfect Square: (x + a)2 = (x + a)(x + a) = x2 + 2ax + a2 (2x - 3)2 = (2x – 3)(2x – 3) = 4x2 – 12x + 9 EXERCISE B Difference of two squares: (x - a)(x + a) = x2 – a2 (x - 3)(x + 3) = x2 – 32 = x2 – 9 Multiply out 1. (x - 1)2 = 4. (x + 2)(x - 2) = 2. (3x + 5)2 = 5. (3x + 1)(3x - 1) = 3. (7x - 2)2 = 6. (5y - 3)(5y + 3)= 5 Section 2: FACTORISING Common factors We can factorise some expressions by taking out a common factor. Example 1: Factorise 12x – 30 Solution: 6 is a common factor to both 12 and 30. We can therefore factorise by taking 6 outside a bracket: 12x – 30 = 6(2x – 5) Example 2: Factorise 6x2 – 2xy Solution: 2 is a common factor to both 6 and 2. Both terms also contain an x. So we factorise by taking 2x outside a bracket. 6x2 – 2xy = 2x(3x – y) Factorise 9x3y2 – 18x2y Example 3: Solution: 9 is a common factor to both 9 and 18. The highest power of x that is present in both expressions is x2. There is also a y present in both parts. So we factorise by taking 9x2y outside a bracket: 9x3y2 – 18x2y = 9x2y(xy – 2) Example 4: Factorise 3x(2x – 1) – 4(2x – 1) Solution: There is a common bracket as a factor. So we factorise by taking (2x – 1) out as a factor. The expression factorises to (2x – 1)(3x – 4) EXERCISE C: Factorise each of the following 1) 3x + xy = 2) 4x2 – 2xy = 3) pq2 4) – p2q 3pq - 9q2 5) 2x3 – 6x2= 2x2(x – 3) 6) 8a5b2 – 12a3b4 = 7) 5y(y – 1) + 3(y – 1) = = = Factorising quadratics Simple quadratics: Factorising quadratics of the form x 2 bx c The method is: Step 1: Form two brackets (x … )(x … ) Step 2: Find two numbers that multiply to give c and add to make b. These two numbers get written at the other end of the brackets. 6 Example 1: Factorise x2 – 9x – 10. Solution: We need to find two numbers that multiply to make -10 and add to make -9. These numbers are -10 and 1. Therefore x2 – 9x – 10 = (x – 10)(x + 1). General quadratics: Factorising quadratics of the form ax 2 bx c The method is: Step 1: Find two numbers that multiply together to make ac and add to make b. Step 2: Split up the bx term using the numbers found in step 1. Step 3: Factorise the front and back pair of expressions as fully as possible. Step 4: There should be a common bracket. Take this out as a common factor. Example 2: Factorise 6x2 + x – 12. Solution: We need to find two numbers that multiply to make 6 × -12 = -72 and add to make 1. These two numbers are -8 and 9. Therefore, 6x2 + x – 12 = 6x2 - 8x + 9x – 12 = 2x(3x – 4) + 3(3x – 4) (the two brackets must be identical) = (3x – 4)(2x + 3) Difference of two squares: Factorising quadratics of the form x 2 a 2 Remember that x 2 a 2 = (x + a)(x – a). Therefore: x 2 9 x 2 32 ( x 3)( x 3) 16 x 2 25 (2 x)2 52 (2 x 5)(2 x 5) Also notice that: and 2 x 2 8 2( x 2 4) 2( x 4)( x 4) 3x3 48xy 2 3x( x 2 16 y 2 ) 3x( x 4 y)( x 4 y) Factorising by pairing We can factorise expressions like 2 x 2 xy 2 x y using the method of factorising by pairing: 2 x 2 xy 2 x y = x(2x + y) – 1(2x + y) both (factorise front and back pairs, ensuring brackets are identical) = (2x + y)(x – 1) 7 EXERCISE D Factorise x2 x 6 = 1) 2) x 2 6 x 16 = 3) 2 x2 5x 2 = 4) 2 x 2 3x = 5) 10 x 2 5 x 30 = 6) 4 x 2 25 = 7) 8) = 8 Section 3: INDICES Basic rules of indices y 4 means y y y y . 4 is called the index (plural: indices), power or exponent of y. There are 3 basic rules of indices: 1) 2) a m a n a mn a m a n a mn e.g. e.g. 3) (a m )n a mn e.g. 34 35 39 38 36 32 3 2 5 310 Further examples y 4 5 y3 5 y 7 4a 3 6a 2 24a 5 2c 2 3c 6 6c8 24d 7 3d 2 24d 7 8d 5 2 3d subtracting (multiply the numbers and multiply the a’s) (multiply the numbers and multiply the c’s) (divide the numbers and divide the d terms i.e. by the powers) EXERCISE E Simplify the following: 1) 2) 3) b 5b5 = (Remember that b b1 ) 3c 2 2c5 = b 2 c bc 3 = 4) 2n6 (6n2 ) = 5) 8n 8 2 n 3 = 6) d 11 d 9 = 9 More complex powers Zero index: Recall from GCSE that a0 1. This result is true for any non-zero number a. 0 3 1 4 5 1 0 Therefore 5.2304 0 1 Negative powers A power of -1 corresponds to the reciprocal of a number, i.e. a 1 5 1 Therefore 1 a 1 5 0.251 1 4 0.25 1 5 4 4 5 (you find the reciprocal of a fraction by swapping the top and bottom over) This result can be extended to more general negative powers: a n 1 . an 1 1 32 9 1 1 4 16 2 32 This means: 24 1 4 2 2 1 1 4 2 16 4 1 Fractional powers: Fractional powers correspond to roots: a1/ 2 a a1/ 3 3 a a1/ 4 4 a In general: a1/ n n a Therefore: 81/ 3 3 8 2 251/ 2 25 5 100001/ 4 4 10000 10 A more general fractional power can be dealt with in the following way: So 43 / 2 8 27 4 2/3 3 a m / n a1/ n m 23 8 2 8 1/ 3 2 2 4 27 3 9 10 25 36 3 / 2 36 25 3/ 2 3 36 6 3 216 125 25 5 EXERCISE F Find the value of: 1) 41/ 2 = 2) 271 / 3 = 3) 19 4) 5 2 = 5) 180 = 6) 7 1 = 7) 27 2 / 3 = 8) 2 = 3 9) 8 2 / 3 10) 0.04 11) 8 27 12) 1 16 1/ 2 = 2 1/ 2 2/3 3 / 2 11 Section 4: SOLVING QUADRATIC EQUATIONS A quadratic equation has the form ax 2 bx c 0 . There are two methods that are commonly used for solving quadratic equations: * factorising * the quadratic formula Note that not all quadratic equations can be solved by factorising. The quadratic formula can always be used however. Method 1: Factorising Make sure that the equation is rearranged so that the right hand side is 0. It usually makes it easier if the coefficient of x2 is positive. Example 1 : Solve x2 –3x + 2 = 0 Factorise (x –1)(x – 2) = 0 Either (x – 1) = 0 or (x – 2) = 0 So the solutions are x = 1 or x = 2 Note: The individual values x = 1 and x = 2 are called the roots of the equation. Example 2: Solve x2 – 2x = 0 Factorise: x(x – 2) = 0 Either x = 0 or (x – 2) = 0 So x = 0 or x = 2 Method 2: Using the formula Recall that the solutions of the quadratic equation ax 2 bx c 0 are given by the formula: x b b 2 4ac 2a Example 3: Solve the equation 2 x 2 5 7 3 x Solution: First we rearrange so that the right hand side is 0. We get 2 x 2 3x 12 0 We can then tell that a = 2, b = 3 and c = -12. Substituting these into the quadratic formula gives: 3 32 4 2 (12) 3 105 (this is the surd form for the solutions) 2 2 4 If we have a calculator, we can evaluate these roots to get: x = 1.81 or x = -3.31 x 12 EXERCISE G 1) Use factorisation to solve the following equations: a) x2 + 3x + 2 = 0 b) x2 – 3x – 4 = 0 2) Find the solutions of the following equations: a) x2 + 3x = 0 x2 – 4x = 0 b) 3) Solve the following equations either by factorising or by using the formula: a) 6x2 - 5x – 4 = 0 b) 8x2 – 24x + 10 = 0 13 Section 5: SIMULTANEOUS EQUATIONS An example of a pair of simultaneous equations is 3x + 2y = 8 5x + y = 11 In these equations, x and y stand for two numbers. We can solve these equations in order to find the values of x and y by eliminating one of the letters from the equations. In these equations it is simplest to eliminate y. We do this by making the coefficients of y the same in both equations. This can be achieved by multiplying equation by 2, so that both equations contain 2y: 3x + 2y = 8 10x + 2y = 22 2× = To eliminate the y terms, we subtract equation from equation . We get: 7x = 14 i.e. x = 2 To find y, we substitute x = 2 into one of the original equations. For example if we put it into : 10 + y = 11 y=1 Therefore the solution is x = 2, y = 1. Remember: You can check your solutions by substituting both x and y into the original equations. Example: Solve 2x + 5y = 16 3x – 4y = 1 Solution: We begin by getting the same number of x or y appearing in both equation. We can get 20y in both equations if we multiply the top equation by 4 and the bottom equation by 5: 8x + 20y = 64 15x – 20y = 5 As the SIGNS in front of 20y are DIFFERENT, we can eliminate the y terms from the equations by ADDING: 23x = 69 + i.e. x=3 Substituting this into equation gives: 6 + 5y = 16 5y = 10 So… y=2 The solution is x = 3, y = 2. 14 EXERCISE H Solve the pairs of simultaneous equations in the following questions: 1) x + 2y = 7 3x + 2y = 9 2) x + 3y = 0 3x + 2y = -7 3) 3x – 2y = 4 2x + 3y = -6 4) 15 Section 3: SOLVING INEQUALITIES The inequality signs: > greater than < less than ≥ greater than or equal to ≤ less than or equal to can be used to define a range of values for a variable. For instance -3 < c ≤ 4 means that the variable c can have any value greater than -3 but less than or equal to 4. Values for c such as -2, 3, 2, -0.5 are all acceptable. Solving Inequalities To solve an inequality you need to find the values of x which make the inequality true. The aim is to end up with one letter on one side of the inequality sign and a number on the other side. You solve inequalities in the same way as solving equations – you do the same thing to both sides. Example 1: Solve the inequality 5x – 3 < 27. 5x -3 < 27 First add 3 to both sides: Divide both sides by 5: 5x < 30 x<6 (so the inequality is true for all values of x less than 6). Example 2: Solve the inequality: 4q + 5 ≥ 12 – 3q. 4q + 5 ≥ 12 – 3q First add 3q to both sides so that the letters appear on one side of the equation: 7q + 5 ≥ 12 Subtract 5 from both sides: 7q ≥ 7 Divide both sides by 7: q ≥ 1. EXERCISE I: Solve the inequality a) 2n – 1 ≤ n + 3. d) 2(4t – 3) 34 b) 4x – 5 < -3 e) 4x + 1 3x – 5 c) 3(x – 2)< 15 f) g) 5w 7 3w 4 5t – 3 2t + 5 16 Multiplying (or dividing) an inequality by a negative number Notice that -2 < 3. Multiply both numbers by -1 : -2 × -1 = 2 and 3 × -1 = -3. The new inequality is 2 > -3. So to keep the inequality true we have to reverse the inequality sign. So… The same rules for equations can be applied to inequalities, with one exception: When you multiply or divide both sides of an inequality by a negative number the inequality is reversed. Example 1: Solve -3x < 6 Divide both sides by -3. Because we are dividing by a negative number the inequality sign is reversed. x > -2 Example 2: Solve 3 – 2d < 5 Method 1: Subtract 3 from both sides: -2d < 2 Divide both sides by -2 and reversing inequality sign: d > -1 Method 2: Add 2d to both sides to get a positive numbers of d’s: 3 < 5 + 2d Subtract 5 from both sides: -2 < 2d Divide both sides by 2: -1 < d or d > -1 Example 3: Solve 8 – x ≤ 12 Subtract 8 from both sides: -x ≤ 4 Multiply both sides by -1 (and reversing inequality sign): x ≥ -4 EXERCISE J Solve the inequalities a) 5 – 3x < 11 b) -4c > 12 c) 2(q – 3) 5 + 7q 17 Practice Booklet Test This is the test. Your test will ask similar questions to this one. You may NOT use a calculator If ax2 + bx + c = 0 then x = 1. 2. b b 2 4ac 2a Expand and simplify (a) (2x + 3)(2x – 1) (b) (a + 3)2 (c) 4x(3x – 2) – x(2x + 5) Factorise (a) x2 – 7x (c) 2x2 + 5x – 3 (d) 6t2 – 13t + 5 (b) y2 – 64 3. Write each of the following as single powers of x and / y 1 x5 (a) 4 (b) (x2y)3 (c) 2 d) 3 x 5 x x 4. Work out the values of the following, giving your answers as fractions 1 (a) 5. 4-2 (b) d) (125) 2 3 Use factorisation to solve the following (a) 8x2 – 4x = 0 6. 3 (c) 8 27 100 b) x2 + 5x – 14 = 0 c) 2x2 – 9x = 5 Find the solutions to the following (a) x2 + 6x + 1 = 0 b) 2x2 =10x + 3 c) 4x2 + 1 = (2 – x)2 7. The equation x2 – 15x + c = 0, where c is a constant, is satisfied by the value x = 2. a) show that c = 26 b) Hence find the solution of this equation. 8. Solve the simultaneous equations 3x – 5y = -11 5x – 2y = 7 9. Solve the simultaneous equations y=x+3 x2 + y2 = 5 Solutions on front page 18