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P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> C H A P T E R 16 MODULE 3 PL E Constructing and interpreting linear graphs How do we find the gradient of a line, given the coordinates of two points? How do we sketch straight line graphs using gradient and y-axis intercept? How do we obtain the equation for a straight line given: r the gradient and y-axis intercept? r the coordinates of two points? How do we construct straight line graphs? M How do we solve linear simultaneous equations for two unknowns? How do we apply linear simultaneous equations to break-even analysis, where cost and revenue functions are linear? The gradient of a straight line Through any two points it is possible to draw only a single straight line. Therefore a straight line is defined by any two points on the line. From previous work, you should be familiar with the rise concept of the gradient or slope of a line. The symbol used for gradient is m. This may be defined as: run rise gradient = run Hence, given any two points on the line, A(x1 , y1 ) y and B(x2 , y2 ), the gradient of the line can be found. B(x2, y2) y2 − y1 gradient m = x2 − x1 rise = y2 – y1 A(x1, y1) SA 16.1 run = x2 – x1 0 x Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with441 Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> 442 Essential Further Mathematics – Module 3 Graphs and relations Example 1 Finding the gradient of a line given two points y Find the gradient of this line. 2 1 –2 –1 Solution E Let (x 2 , y 2 ) = (0, 2) and let (x 1 , y 1 ) = (−2, 0) y2 − y1 2−0 Gradient m = = x2 − x1 0 − (−2) 2 = =1 2 PL 1 From the graph, identify two points where the coordinates can be easily determined. In this case the axes intercepts are chosen (2, 0) and (0, 2). y2 − y1 2 Use m = x2 − x1 x 0 Example 2 Finding the gradient of a line given two points y Find the gradient of this line. 3 2 1 Solution 0 2 x Let (x 1 , y 1 ) = (0, 3) and (x 2 , y 2 ) = (2, 0) y2 − y1 0−3 m= = x2 − x1 2−0 3 =− 2 M 1 From the graph identify two points where the coordinates can be easily determined. In this case the axes intercepts are chosen (2, 0) and (0, 3). 3 y2 − y1 =− 2 Use m = x2 − x1 2 SA 1 The gradient of a line that slopes upwards from left to right is positive, and the gradient of a line that slopes downwards from left to right is negative. The gradient of a horizontal line is zero, since y2 − y1 = 0. The gradient of a vertical line is undefined, since x2 − x1 = 0. Exercise 16A 1 Calculate the gradient of each of the following. a b y c y y 6 4 2 6 4 0 2 –4 –2 0 –2 x 2 (3, 0) (0, –4) x –2 0 2 x 4 6 4 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 443 d e y f y y (6, 0) (–3, 0) x 0 x –5 –5 (0, –4) 2 Sketch a graph of a line with gradient 1. 3 Sketch a graph of a line with gradient 0. 0 x E (–2, 0) 4 Find the gradients of the lines that pass through each of the following pairs of points: d (10, 16) (12, 0) h (−5, 25) (−8, 64) The general equation of a straight line The general equation of a straight line is y = mx + c, where m is the gradient of the line. This form, expressing the relation in terms of y, is called the gradient form. If we let x = 0, we get M y = m(0) + c y=c That is, the y-axis intercept is equal to c. Example 3 Interpreting the equation of a line given the form y = mx + c Find the gradient and y-axis intercept of the graph of y = 3x − 4. SA 16.2 b (−6, 8) (2, −12) c (3, 3.5) (5.5, −1.5) f (0, −3) (−3, 0) g (3, 9) (4, 16) PL a (12, 6) (4, 8) e (3, 0) (−3, 0) Solution The equation of the line is in the form y = mx + c where m is the gradient and c the y-axis intercept. The value of m is 3 and the value of c is −4. Therefore the gradient of this line is 3 and the y-axis intercept is −4. If we are given the rule of a straight line, we can sketch the graph using the gradient and the y-axis intercept. Example 4 Sketching straight-line graphs Sketch the graph of y = 3x − 1. Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> 444 Essential Further Mathematics – Module 3 Graphs and relations Solution 1 The equation is written in the form y = mx + c. Hence the gradient and y-axis intercept can be read directly. 3 rise = Gradient = 3, i.e. run 1 y-axis intercept = −1 y (1, 2) 2 E 2 Plot the point (0, −1), the y-axis intercept. 3 A gradient of 3 means that for every unit across in the positive x-axis direction you go up 3 in the positive y-axis direction. From the y-axis intercept move across 1 (run) and up 3 (rise) to plot the point (1, 2). 4 Draw a line through the points (0, −1) and (1, 2) to sketch the graph. 1 3 0 –1 x 1 PL –1 1 If the equation for the straight line is not written in gradient form, to use the above method for sketching a graph the equation must first be transposed into gradient form. Example 5 Sketching a straight-line graph M Sketch the graph of 3y + 6x = 9. Solution SA 1 First rearrange the equation into gradient form: y = mx + c 3y + 6x = 9 ∴ 3y = 9 − 6x (subtracting 6x from both sides) 9 − 6x (dividing both sides by 3) y = 3 y = 3 − 2x ∴ y = −2x + 3 2 The equation is now written in the form y = mx + c. Therefore m = −2 and c = 3 3 A gradient of −2 means that for every unit across in the positive x-axis direction you go down 2 in the negative y-axis direction. From the y intercept (0, 3) move across 1 (run) and down 2 (rise) to plot the point (1, 1). 4 Draw a line through the points (0, 3) and (1, 1) to sketch the graph. y 1 3 –1 2 2 1 (1, 1) 0 –1 x 1 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 445 Parallel lines y If the value of m is the same for two rules, then the lines are parallel. For example, consider the lines with rules y = 2x + 3 4 Exercise 16B 1 2 –4 PL 1 Sketch the graph of each of the following: x –1 0 –2 E –2 They are parallel because they both have the same gradient, m = 2. a y = x +1 d y =4−x y = 2x – 4 2 y = 2x + 3 y = 2x − 4 b y = 2x + 1 e y = 4 − 2x c y = 3x − 6 f y = −x + 6 2 For which of the following equations do the lines pass through the origin? a y+x =1 b y+x =0 c 2y = 3x d y + 3x = 3(x + 1) e x−y=1 3 Give the gradient of each of the lines in Question 2. 4 Sketch the graph of each of the following by first expressing it in the form y = mx + c. c 6y − 4x = 24 f 2y + 3x = 6 i 2x − 3y = 6 Finding the equation of a straight line The equation of a straight line can be found if the gradient and y-axis intercept are known. SA 16.3 b 6x + 3y = 12 e y − 2x = 6 h y − 2x = 1 M a 4x + 2y = 12 d x+y=3 g x + 2y = 1 Example 6 Finding the equation of a straight line Write down the equation of the straight line if m = −3 and c = 10. Solution The equation is y = −3x + 10. If, however, we are not told the gradient and/or the y-axis intercept, they can be determined from other information. y Case (i) We are given any two points A(x 1 , y1 ) B(x2, y2) and B(x2 , y2 ). Using these two points, we can first P(x, y) calculate the gradient of the line AB: A(x1, y1) y2 − y1 x m= 0 x2 − x1 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> 446 Essential Further Mathematics – Module 3 Graphs and relations Using the general point P (x, y), also on the line, we have: m= y − y1 x − x1 Therefore the equation of the line is: y − y1 = m(x − x1 ) where m = Example 7 y2 − y1 x2 − x1 E Finding the equation of a straight line Find the equation of the straight line passing through the points (1, −2) and (3, 2). y 2 1 PL 0 –2 (3, 2) 2 3 x 4 (1, –2) –4 Solution 1 First find the gradient using m= y2 − y1 x2 − x1 x 1 = 1, y 1 = −2, x 2 = 3 and y 2 = 2 2 − (−2) 4 = =2 3−1 2 M 2 Now use y − y1 = m(x − x1 ) to determine y − (−2) = 2(x − 1) ∴ y = 2x − 4 the equation. 3 Write down your answer. The equation of the straight line is y = 2x − 4. We are given the gradient m and one other point, A(x1 , y1 ). Since we already know the gradient m we can find the rule using Case (ii) SA y − y1 = m(x − x1 ) Example 8 Finding the equation of a straight line Find the equation of the line that passes through the point (3, 2) and has a gradient of −2. Solution 1 Since we already know the gradient m and a point on the line, we can find the rule, using y − y1 = m(x − x1 ). Write down the values of m, x1 and y1 . Substitute and reorganise the equation to make y the subject. 2 Write down your answer. m = −2, x 1 = 3 and y 1 = 2 y − 2 = −2(x − 3) y − 2 = −2x + 6 ∴ y = −2x + 8 The equation of the line is y = −2x + 8. Note: The equation could also be expressed as y + 2x − 8 = 0. Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 447 The equation of a straight line can also be found from the graph by reading off two points and using them to find the equation, as outlined above. Example 9 Finding the equation of a line given its graph y Find the equation of the line shown in the graph. A E 4 3 2 1 0 Solution x The y-axis intercept is (0, 4), so c = 4. The coordinates of A and B are (0, 4) and (2, 0): PL 1 The equation of a straight line is y = mx + c. 2 c is the y-axis intercept. Read from the graph. 3 m is the gradient. Calculate using the two points A and B. 4 Write down your answer. B 1 2 y2 − y1 x2 − x1 0−4 4 = = − = −2 2−0 2 ∴ gradient m = The equation of the line is y = −2x + 4. M Vertical and horizontal lines If m = 0, then the line is horizontal and the equation is simply y = c, where c is the y-axis intercept. Example 10 Horizontal lines SA Sketch the graph of y = 2. Solution 1 The equation of a straight line is y = mx + c. 2 For this equation the y-axis intercept is 2 and the gradient is 0. The line is parallel to the x axis. 3 Draw a horizontal line passing through (0, 2). y 3 (0, 2) y=2 1 0 If the line is vertical, the gradient is undefined and its rule is given as x = a, where a is the x-axis intercept. Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin x P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> 448 Essential Further Mathematics – Module 3 Graphs and relations Example 11 Vertical lines Sketch the graph of x = 3. Solution y 1 Note that the equation of a vertical line is not in the form y = mx + c. 2 For this equation, the graph is the line which consists of all points with coordinates (3, y) and y varies. 3 Draw a vertical line passing through (3, 0). E x=3 (3, 0) 0 PL Exercise 16C 1 2 3 x 4 1 Find the equation of each of the following straight lines. y a M SA 2 y g –3 y x x x 0 e 0 0 1 2 x 0 y d y c 6 2 –1 y b y f 2 x 0 –3 –2 0 x y h 3 01 2 x 0 x 8 2 Find the equation of each of the following straight lines defined by: a gradient 12 , passing through (0, 1) c gradient 0, passing through (0, 6) e gradient −2, passing through (1, 3) b gradient 2, passing through (1, 4) d gradient 1, passing through (2, −4) 3 Write in the form y = mx + c the equation of the line that has the given gradient and passes through the given point: b 12 , (0, 6) c −3, (1, 4) a 32 , (0, 1) Cambridge University Jones, d −1, (0, 2)Press • Uncorrected Sample e −2,pages (−1, •4)978-0-521-61328-6f• 2008 −1,©(3, 7) Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 449 4 Find the equation of the line that passes through each of the following pairs of points: b (−3, 0)(0, −6) e (1, 4) (5, 6) a (0, 3) (3, 0) d (0, 1)(−1, 0) Equation of a straight line in intercept form ax + by = c E Often we encounter a linear relation that is not expressed in the form y = mx + c. An alternative standard notation is PL This is sometimes referred to as intercept form. While it is necessary to transpose into gradient form if you wish to find the gradient, it is often convenient to work with linear relations in the intercept form. Sketching graphs in intercept form A convenient way to sketch graphs of straight lines is to plot the two axes intercepts. Example 12 Sketching the graph of a line given in intercept form Sketch the graph of 2x + 4y = 10. Solution x-axis intercept (y = 0): M 1 Find the x-axis intercept. ∴ 2x + 4(0) = 10 or x = 5 y-axis intercept (x = 0): 2 Find the y-axis intercept. ∴ 2(0) + 4y = 10 or y = 2.5 y 3 Use the two points to sketch the line. SA 16.4 c (0, 4) (4, 2) 2.5 0 x 1 2 3 4 5 When finding the equation of a straight line, it is also sometimes more convenient to express it in intercept form. Example 13 Finding the equation of a line given two points Find the equation of the line passing through the points A (2, 5) and B (6, 8). Solution 1 Find the gradient of the line. m = 3 8−5 = 6−2 4 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Essential Further Mathematics – Module 3 Graphs and relations 2 Use y − y1 = m(x − x1 ) to find the equation. Here y1 = 5 and x1 = 2. Substitute for m, x1 and y1 , and rearrange into the intercept form. 3 y − 5 = (x − 2) 4 ∴ 4(y − 5) = 3(x − 2) ∴ 4y − 20 = 3x − 6 4y − 3x = 14 3 Write down your answer. The equation of the line is 4y − 3x = 14 or −3x + 4y = 14 Exercise 16D E 450 1 Sketch the graph of each of the following linear relations: b 4x − y = 8 e −3x + 4y = 15 c 3x − 4y = 24 f 7x − 2y = 14 PL a 2x − 3y = 12 d 2x − 5y = 20 2 Transpose each of the following linear relations from intercept form to gradient form and hence state the gradient: a 2x − y = 6 d 5x − 2y = 10 16.5 b x + 4y = 12 e x − 5y = 10 c −x − 2y = 6 f −x + 2y = 8 Linear models M In many practical situations a linear rule can be used. Example 14 Application of linear rules and graphs SA Austcom’s rates for local calls from private telephones consist of a quarterly rental fee of $40 plus 25c for every call. Construct a linear rule that describes the quarterly telephone bill and sketch the graph. Solution Strategy: Construct a linear rule of the form C = mn + c by finding the gradient m and the C-axis intercept. Let C n C -axis intercept Gradient m ∴C = cost ($) of quarterly telephone bill = number of calls = 40 = 0.25 = 0.25n + 40 C 100 80 (200, 90) 60 40 20 50 100 150 200 n Note: The graph should be a series of discrete points rather than a continuous line. With the scale used it is not practical to show it correctly. Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 451 Example 15 Application of linear rules and graphs The tyres on a racing car had lost 3 mm of tread after completing 250 km of a race and 4 mm of tread after completing 1000 km. Assuming that the loss of tread was proportional to the distance covered, find the total loss of tread, d mm, after s km from the start of the race. What would be the tread loss by the end of a 2000 km race? Solution d (mm) PL Rule : d = m s + c rise Gradient, m = run 1 4−3 = = 1000 − 250 750 1 s+c ∴ d= 750 When s = 250, d = 3 1 2 ∴ 3 = + c or c = 2 3 3 E Strategy: Construct a rule of the form d = ms + c by finding the gradient m and the d-axis intercept. ∴ Total loss of tread after s km, d = 0 250 When rise run 1000 s (km) 1 2 s + 23 750 M s = 2000 1 2 d= × 2000 + 2 3 750 1 =5 3 4 3 1 SA The loss of tread at the end of a 2000 km race is 5 3 mm. Exercise 16E 1 The weekly wage, $w, of a vacuum cleaner salesperson consists of a fixed sum of $350 plus $20 for each cleaner sold. If n cleaners are sold per week construct a rule that describes the weekly wage of the salesperson. 2 The reservoir feeding an intravenous drip contains 500 mL of a saline solution. If the drip releases the solution into a patient at the rate of 2.5 mL/min: a construct a rule that relates v, the amount of solution left in the reservoir after time, t minutes b state the possible values of t and v c sketch the graph of the relation 3 The cost ($C) of hiring a taxi consists of two elements, a fixed flagfall and a figure that varies with the number (n) of kilometres travelled. If the flagfall is $2.60 and the cost per Cambridge University Press •determine UncorrectedaSample pages • 978-0-521-61328-6 kilometre is $1.50, rule that gives C in terms of n.• 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> 452 Essential Further Mathematics – Module 3 Graphs and relations 4 A car rental company charges $85, plus an additional amount of 24 cents per kilometre. a Write a rule to determine the total charge $C for hiring a car and travelling x kilometres. b What would be the cost to travel 250 kilometres? 5 The table shows the extension (in cm) of a spring when weights (in g) are attached to it. extension (x) 0 1 2 3 4 5 6 weight (w) 50 50.2 50.4 50.6 50.8 51.0 51.2 E a Sketch a graph to show the relationship between x and w. b Write a rule that describes the graph. c What will the extension be if w = 52.5 g? 6 A printing firm charged $35 for printing 600 sheets of headed notepaper and $47 for printing 800 sheets. PL a Find a formula, assuming the relationship is linear, for the charge, $C, in terms of number of sheets printed, n. b How much would they charge for printing 1000 sheets? 7 An electronic bankteller registered $775 after it had counted 120 notes and $975 after it had counted 160 notes. a Find a formula for the sum registered ($C) in terms of the number of notes (n) counted. (Assume the formula connecting C and n is of the form C = an + b). b Was there a sum already on the register when counting began? If so, how much? M 8 An electrician charges $50 to call and $80 per hour. Assuming that the relationship between charge and time is linear: a find a formula for $C, the charge in terms of the time spent (t hours) b draw a graph of C against t c calculate the cost of a job that takes 2 hours 45 minutes to complete SA 9 The table shows the conversion from British pounds to Australian dollars for various amounts of money. a b c d 16.6 Australian dollars ($) 46 British pounds (£) 20 92 184 40 80 Plot these points and draw a straight line through them. What does the gradient of the straight line represent? State the gradient. Find a formula for $A in terms of £P, British pounds. Simultaneous equations A linear equation that contains two unknowns (e.g. 2y + 3x = 10) does not have a single solution. Such an equation actually expresses a relationship between pairs of numbers, x and y, that satisfy the equation. If we represent graphically all the possible pairs of numbers (x, y) that will satisfy the equation, the result is a straight line. Hence the name linear relation. If the graphs of two such equations are drawn on the same set of axes, and they are non-parallel, the lines will intersect at one point only. Hence there is one pair of numbers that will satisfy both equations simultaneously. Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 453 –y 4 3 2 –3 –2 –1 1 1 2 3 x 0 –1 –2 x+ E –3 –4 (1, –2) 2y = –3 Solving a pair of simultaneous equations PL Example 16 =4 y 2x Finding the intersection of two straight lines can be done graphically; however, the accuracy of the solution will depend on the accuracy of the graphs. Alternatively this point of intersection can be found algebraically by solving the pair of simultaneous equations. We will look first at two techniques for solving simultaneous equations. Solve the equations 2x − y = 4 and x + 2y = −3. Solution By substitution 1 Write down the equations and label them 1 and 2. M 2 Express one unknown from either equation in terms of the other unknown. 3 Then substitute this expression into the other equation, reducing it to one equation in one unknown. 4 Solve this equation SA 5 Substitute the value of y into (2): 6 Check in Equation 1 2x − y = 4 x + 2y = −3 (1) (2) From equation (2) we get: x = −3 − 2y Equation (1) then becomes: 2(−3 − 2y ) − y = 4 ∴ −6 − 4y − y = 4 ∴ −5y = 10 ∴ y = −2 x + 2(−2) = −3 ∴ x =1 Check in (1) LHS = 2(1) − (−2) = 4 RHS = 4 Note: This means that the point (1, −2) is the point of intersection of the graphs of the two linear relations. By elimination Strategy: If the coefficient of one of the unknowns is the same in both equations, we can eliminate that unknown by subtracting one equation from the other. It may be necessary to multiply one of the equations by a constant to make the coefficients of x or y the same for the two equations. Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> 454 Essential Further Mathematics – Module 3 Graphs and relations 2x − y = 4 (1) x + 2y = −3 (2) 2x + 4y = −6 (2 ) 1 Write down the equations and label them 1 and 2. 2 To eliminate x, multiply equation (2) by 2 and subtract the result from equation (1). 3 Subtracting (1) − (2 ) ∴ −5y = 10 (1) − (2 ) or y = −2 2x − (−2) = 4 or x = 1 E 4 Now substitute for y in (1) to find x 5 Check as in the substitution method. ∴ PL How to to solve simultaneous equations using the TI-Nspire CAS Solve the following pair of simultaneous equations: 24x + 12y = 36 45x + 30y = 90 Steps 1 Start a new document and select 1:Add Calculator. M 2 Press b /3:Algebra/1:Solve to paste the solve( command. SA and select the template 3 Press / + shown opposite. 4 Enter the values as shown. Use the key to move between entry boxes. 5 Press to move to the end of . the equations and type 6 Press enter to display the solution. 7 The solution x = 0 and y = 3 can be checked by substitution. 24 × 0 + 12 × 3 = 36 45 × 0 + 30 × 3 = 90 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 455 How to solve simultaneous linear equations algebraically using the ClassPad Steps 1 From the application menu screen, open the Main application, . PL 2 Press k on the front of the calculator to display the built-in keyboard. Tap the ) tab and locate and tap the . simultaneous equations icon Enter the information 24x + 12y = 36 45x + 30y = 90 E Solve the following pair of simultaneous equations: 24x + 12y = 36 45x + 30y = 90 x,y M Press E to display the solution x = 0 and y = 3. 3 The solution x = 0 and y = 3 can be checked by substitution. SA 24 × 0 + 12 × 3 = 36 45 × 0 + 30 × 3 = 90 Exercise 16F 1 Solve each of the following pairs of simultaneous linear equations using either the substitution or elimination method. Check your answers with your calculator. a x + 2y = 6 x + 3y = 4 b 7x + 6y = 0 5x − 6y = 48 c 3x + 2y = 12 x + 2y = 8 d x − 2y = 6 4x + 2y = 14 e x + 3y = 12 x+y=8 f 9x + 2y = 48 x − 2y = 2 g 2x + 3y = 13 2x + 5y = 21 h 3x − y = 10 x + y = −2 i 3 p + 5q = 17 4 p + 5q = 16 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> 456 Essential Further Mathematics – Module 3 Graphs and relations j 2x + 3y = 12 5x + 4y = 23 l 9x + 8y = 17 2x − 6y = −4 m y =6−x 2x + y = 8 n 9+x = y x + 2y = 12 o 2y = 4 + x y = x +8 p x +4= y y = 10 − 2x q y =4−x y = x +6 r y = 4 + 2x y − 2x = 6 Problems involving simultaneous linear equations E 16.7 k 5x + 4y = 21 3x + 6y = 27 Example 17 Application of simultaneous linear equations Solution PL There are two possible methods for paying gas bills: Method A: A fixed charge of $25 per quarter + 50c per unit of gas used Method B: A fixed charge of $50 per quarter + 25c per unit of gas used Determine the number of units that must be used before method B becomes cheaper than method A. M 1 Set up the equations. C 1 = charge in $ using method A C 2 = charge in $ using method B x = number of units of gas used Now C 1 = 25 + 0.5x C 2 = 50 + 0.25x Let C 100 Dollars SA 2 Graph the two straight lines and find the point of intersection. 75 C1 = 0.5x + 25 (100, 75) C2 = 0.25x + 50 50 25 0 x 25 50 75 100 125 150 Units 3 Write down your answer. It can be seen from the graph that if the number of units exceeds 100 then method B is cheaper. Note: The solution could also be obtained by solving simultaneous linear equations: C1 25 + 0.5x 0.25x ∴x = C2 = 50 + 0.25x = 25 = 100 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 457 Example 18 Application of simultaneous linear equations If 3 kg of jam and 2 kg of butter cost $29, and 6 kg of jam and 3 kg of butter cost $54, find the cost of 1 kg of jam and 1 kg of butter. Solution Then and 3x + 2y = 29 (1) 6x + 3y = 54 (2) Multiply (1) by 2 : 6x + 4y = 58 (1 ) Subtract (1 ) from (2) : PL 2 Solve the equations, or use your calculator. Let the cost of 1 kg of jam = x dollars and the cost of 1 kg of butter = y dollars. E 1 Set up the equations. 3 Write down your answer. −y = −4 y =4 Substituting in (2) gives : 6x + 3(4) = 54 6x = 42 ∴x =7 ∴ The jam costs $7 per kilogram and the butter $4 per kilogram. M Exercise 16G 1 Find two numbers whose difference is 9 and whose sum is 11. 2 The sum of two numbers is 73 and their difference is 37. Find the numbers. SA 3 The sum of two numbers is 20 and their difference is 4. Find the numbers. 4 Find two numbers where twice the first added to the second is 26 and the first added to three times the second is 28. 5 A cup and a saucer cost $5.25 together. A cup and two saucers cost $7.50. Find the cost of a cup. 6 A shop sells bread rolls. If five brown rolls and six white rolls cost $2.94 and three brown rolls and four white rolls cost $1.86 find the cost of each type of roll. 7 In a test, the sum of Anne’s mark and David’s mark is 42. Sheila has twice as many marks as David and the sum of Anne’s and Sheila’s marks is 52. What are the marks of the three students? 8 A herbalist wishes to prepare a mixture from two herbs, A and B. The mixture costs $6 per kilogram. If herb A costs $5 per kilogram and herb B costs $8 per kilogram and 60 kilograms of the mixture is to be prepared, how many kilograms of each herb should be used? Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> 458 Essential Further Mathematics – Module 3 Graphs and relations 9 The cost ($C) of printing a pamphlet is given by the expression C = a + bn, where n is the number of pamphlets, $a is the fixed cost of printing and $b is the cost per pamphlet. a If it costs $460 to print 80 pamphlets and $1060 to print 200 pamphlets find: i a ii b b Find the cost of printing 500 pamphlets. c Sketch the graph of C against n. 16.8 Break-even analysis 0 E demand curve Quantity 0 For a price of $b consumers purchase a units. Example 19 supply curve $ Price/unit (a, b) (c, d) PL $ Price/unit For each price of a product a corresponding quantity of the product will be demanded (purchased) during some time interval. The quantities of a product that can be demanded or supplied can be represented graphically. Quantity If c units are produced the price is $d. Break-even analysis M A firm sells its product at $20 per unit. The cost of production ($C) is given by the rule C = 4x + 48, where x is the number of units produced. Find the value of x for which the cost of production of x units is equal to the revenue received by the firm for selling x units. Solution SA 1 Set up the equations. Let the revenue for producing x units be $R. R = 20x C = 4x + 48 2 Draw the graphs. 3 Find the point of intersection. R, C R = 20x break-even point Quantity When C = 4x + 48 x C =R 20x = 4x + 48 ∴ x =3 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 459 From the graph: If less than three items are produced C > R. If more than three items are produced C < R. The point where R = C is called the break-even point. Exercise 16H E 1 Find the break-even point if sales revenue ($S) is given by the rule S = 0.75x, where x is the number of items sold and the cost ($C) is given by the rule C = 0.25x + 100. 2 Find the break-even point for each of the following, where $C is the cost in producing x units, and the sales price per unit is $n: b C = 12x + 84; n = 40 e C = 30x + 350; n = 100 c C = 90x + 60; n = 100 f C = 400x + 800; n = 500 PL a C = 2x + 16; n = 10 d C = 3x + 39; n = 16 3 A manufacturer sells his product at $72 per unit, selling all that he produces. His fixed cost is $45 000 and the cost per unit is $22. Find: a b c d the break-even point the profit when 1800 units are produced the loss when 450 units are produced the sales volume required in order to obtain a profit of $90 000 M 4 A manufacturer of a product sells all that he produces. If his total revenue is given by R = 7x (dollars) and his total cost is given by C = 6x + 800 (dollars), where x represents the number of units produced and sold, then: SA a determine the level of production at the break-even point b sketch the graph of C and R against x c determine the level of production at the break-even point if the total cost increases by 5% 5 For each of the following $R is the total revenue and $C is the total cost. If x represents both the number of units produced and the number of units sold, determine the break-even quantity and sketch a graph of R and C against x for each. a R = 3x C = 2x + 4500 b R = 14x c R = 1.05x d R = 0.25x 22 x + 1200 C= C = 0.85x + 600 C = 0.16x + 360 3 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Essential Further Mathematics – Module 3 Graphs and relations Key ideas and chapter summary rise Gradient = run rise Gradient = run Gradient rise run E Given any two points on the line, A(x1 , y1 ) and B(x2 , y2 ), the gradient of the line can be found. Gradient, coordinate definition gradient m = y y2 − y1 x2 − x1 PL B(x2, y2) A(x1, y1) rise = y2 – y1 run = x2 – x1 x 0 Gradient, sign of The gradient of a line that slopes upwards from left to right is positive, and the gradient of a line that slopes downwards from left to right is negative. M Gradient–axis intercept form The general equation of a straight line is y = mx + c, where m is the gradient of the line. This form, expressing the relation in terms of y, is called the gradient form. The y-axis intercept is c. Finding equation of straight line given two points SA Review 460 Finding equation of straight line given gradient and a point Given any two points A(x1 , y1 ) and B(x2 , y2 ), the equation of the line is: y2 − y1 y − y1 = m(x − x1 ) where m = x2 − x1 y B(x2, y2) P(x, y) A(x1, y1) 0 x If we are given the gradient m and one other point, A(x1 , y1 ), we can find the rule using: y − y1 = m(x − x1 ) Horizontal lines If m = 0, then the line is horizontal and the equation is simply y = c, where c is the y-axis intercept. Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 461 Intercept form of a straight line ax + by = c This is sometimes referred to as intercept form. Simultaneous equations Equations of two or more lines or curves in a cartesian plane, the solution of which is the point of intersection of the pairs of lines or curves. Break-even point The break-even point of a production process is where the cost of production is equal to the income received. E If the line is vertical, the gradient is undefined and its rule is given as x = a, where a is the x-axis intercept. C = 4x + 48 break-even point PL R, C R = 20x Quantity Skills check M Having completed this chapter you should be able to: sketch a straight line given the coordinates of two points sketch a straight line given gradient and a point interpret linear graphs which model real-life situations solve linear simultaneous equations by both algebraic and graphical techniques use simultaneous equations to solve problems use break even analysis to solve problems SA Multiple-choice questions Questions 1 to 4 refer to the graph below y line A 5 4 3 2 1 –2 –1 –10 –2 –3 line B –4 –5 1 2 1 The slope of line A is: B −2 A − 12 3 4 5 line C x C 2 D − 32 E −5 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin Review Vertical lines P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Essential Further Mathematics – Module 3 Graphs and relations 2 The equation of line B is: A y − 2x = 3 D −2y − x = 6 B x−y=3 E y+x =3 3 The equation of line C is: A y = −x B y = −1 C y−x =3 C x =1 D x = −y E y=1 D (−1, −4) E (0, 1) E 4 Lines B and C intersect at the point: A (1, 4) B (4, 1) C (−4, −1) 5 The solution of the simultaneous equations 2x − y = 10 and x + 2y = 0 is: A x = −2 and y = 3 B x = 2 and y = −3 C x = 4 and y = −2 D x = 6 and y = 2 E x = 1 and y = −8 PL 6 A straight line has gradient 3 and passes through the point with coordinate (1, 9). The equation of the line is: A y = x +9 B y = 3x + 9 C y = 3x + 6 1 1 E y = −3x + 6 D y = −3x + 1 7 If two lines 5x − y + 7 = 0 and ax + 2y − 11 = 0 are parallel then a equals: A −5 B 5 C −10 D 10 E −1 2 M 8 The cost ($C) of hiring a car is given by the formula C = 2.5x + 65 where x is the number of kilometres travelled. A person is charged $750 for the hire of the car. The number of kilometres travelled was: A 65 B 145 C 160 D 200 E 274 9 If Sue buys 3 packets of chips and 2 bottles of Coke it will cost her $13.20. However, if she buys 2 packets of chips and 3 bottles of Coke it will cost her only $11.80. The price of each item is: A coke = $3.20, chips = $1.80 B coke = $2.10, chips = $3 C coke = $1.80, chips = $3.20 D coke = $2, chips = $2.90 E coke = $1.20, chips = $2 SA Review 462 10 The equation of the line passing through (5, 9) and parallel to the line y = 3x + 7 is: B y = − 13 x + 7 C y = 3x − 6 A y = − 13 x + 7 13 D y = 3x + 7 E y = 3x + 9 11 The cost ($C) of renting a truck is given by the formula C = 1.5x + 20 where x is the number of kilometres travelled. A person is charged $320 for the rental of a truck. The number of kilometres travelled was: A 100 B 120 C 200 D 400 E 500 12 The graph of 3x − 2y = −6 is: y y B A 3 –2 0 y C y D 3 3 x 0 y E x 2 0 –3 2 x –3 0 –2 x –2 0 –3 x Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Chapter 16 – Constructing and interpreting linear graphs 463 Review 13 Which of the following points lie on both the line with equation y = 3x − 1 and the line with equation 4x + 2y = 8? A (0, 0) B (0, 4) C (2, 0) D (1, 2) E (2, 1) 14 The gradient of the line with equation 2x + 4y − 6 = 0 is: B 2 C 4 D −2 A − 12 E 1 x + y = 219 x + 2y = 361 E 15 The cost to enter a fun run was $2.00 per senior runner and $1.00 per junior runner. The total number of runners was 219 and the total of the entry fees paid was $361. If the number of senior entries was x and the number of junior entries was y, which one of the following pairs of simultaneous equations is satisfied by x and y? A x + y = 361 B x + y = 219 C x + y = 361 2x + y = 219 2x + y = 361 x + 2y = 219 PL E x + y = 219 y x + = 361 2 16 The equation of the straight line that passes through the points with coordinates (−2, 5) and (2, −5) is: A 5x + 2y = 0 B 7x − 5y + 45 = 0 C 5x − 7y = 45 D 7x − 5y = 45 E 5x + 7y + 45 = 0 D SA M 17 The equation of the line shown in the diagram is: x y y x B + =1 + =1 A 4 3 3 4 x y − = 1 D 4y − 3x = 12 C 4 3 E 3x + 4y + 25 = 0 y (0, 4) 0 x (3, 0) y 18 The equation of the line passing through the point (2, 3) and parallel to the x axis is given by: A x+y=5 B y=3 C x =2 D x − y = −1 E 3x = 2y (2, 3) 0 x 19 The solution of the system of equations 2x + y = 1 and y + 14 = 3x is: A x =5 y=1 B x = 3 y = −5 C x =5 y=3 D x = −5 y = 3 E x = 1 y = −11 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin P1: FXS/ABE P2: FXS 9780521740517c16.xml CUAU031-EVANS September 6, 2008 13:38 Back to Menu >>> Essential Further Mathematics – Module 3 Graphs and relations M PL E 20 Given the straight line 2x + 3y − 6 = 0, which of the following statements is not true? A If x increases then y decreases. B The line has a negative gradient. C The gradient of the line is −2. D The line intercepts the x axis at 3 and the y axis at 2. E The line is parallel to the line with the equation 2x + 3y − 4 = 0. SA Review 464 Cambridge University Press • Uncorrected Sample pages • 978-0-521-61328-6 • 2008 © Jones, Evans, Lipson TI-Nspire & Casio ClassPad material in collaboration with Brown and McMenamin
