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KS3 Mathematics A5 Functions and graphs
The aim of this unit is to teach pupils to: Express functions and represent mappings Generate points and plot graphs of functions Material in this unit is linked to the Key Stage 3 Framework supplement of examples pp A5 Functions and graphs
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A5.5 Graphs of functions
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(3, 5) (3, 5) (3, 5) Coordinate pairs
When we write a coordinate, for example, (3, 5) (3, 5) (3, 5) x-coordinate y-coordinate the first number is called the x-coordinate and the second number is called the y-coordinate. the first number is called the x-coordinate and the second number is called the y-coordinate. Link: S4 Coordinates and transformations 1 - coordinates Together, the x-coordinate and the y-coordinate are called a coordinate pair.
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Graphs parallel to the y-axis
What do these coordinate pairs have in common? (2, 3), (2, 1), (2, –2), (2, 4), (2, 0) and (2, –3)? The x-coordinate in each pair is equal to 2. Look what happens when these points are plotted on a graph. x y All of the points lie on a straight line parallel to the y-axis. Stress that as long as the x-coordinate is 2 the y-coordinate can be any number: positive negative or decimal. Encourage pupils to be imaginative in their choice of points that lie on this line. For example, (2, ) (2, 43/78) or (2, – ). Name five other points that will lie on this line. This line is called x = 2. x = 2
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Graphs parallel to the y-axis
All graphs of the form x = c, where c is any number, will be parallel to the y-axis and will cut the x-axis at the point (c, 0). x y Stress that the graph of x = ‘something’ will always be parallel to the y-axis. In other words, it will always be vertical (not horizontal like the x-axis). For each graph shown in the example, ask pupils to tell you the coordinate of the point where the line cuts the x-axis. Ask pupils to tell you the equation of the line that coincides with the y-axis (x = 0). x = –10 x = –3 x = 4 x = 9
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Graphs parallel to the x-axis
What do these coordinate pairs have in common? (0, 1), (4, 1), (–2, 1), (2, 1), (1, 1) and (–3, 1)? The y-coordinate in each pair is equal to 1. Look what happens when these points are plotted on a graph. x y All of the points lie on a straight line parallel to the x-axis. Stress that as long as the y-coordinate is 1 the x-coordinate can be any number: positive negative or decimal. Encourage pupils to be imaginative in their choice of points that lie on this line. For example, (1, ) (1, 56/87) or (1, – ). y = 1 Name five other points that will lie on this line. This line is called y = 1.
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Graphs parallel to the x-axis
All graphs of the form y = c, where c is any number, will be parallel to the x-axis and will cut the y-axis at the point (0, c). x y y = 5 y = 3 Stress that the graph of y = ‘something’ will always be parallel to the x-axis. In other words, it will always be horizontal (not vertical like the y-axis). For each graph shown in the example, ask pupils to tell you the coordinate of the point where the line cuts the y-axis. Ask pupils to tell you the equation of the line that coincides with the x-axis (y = 0). y = –2 y = –5
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Drawing graphs of functions
The x-coordinate and the y-coordinate in a coordinate pair can be linked by a function. What do these coordinate pairs have in common? (1, 3), (4, 6), (–2, 0), (0, 2), (–1, 1) and (3.5, 5.5)? In each pair, the y-coordinate is 2 more than the x-coordinate. These coordinates are linked by the function: Ask pupils if they can visualize the shape that the graph will have. This might be easier if they consider the points (0, 2), (1, 3), (2, 4) (3, 5) etc. Establish the the points will lie on a straight diagonal line. Stress that the graphs of all linear functions are straight lines. A function is linear if the variables are not raised to any power (other than 1). Ask pupils to suggest the coordinates of any other points that will lie on this line. Praise the most imaginative answers. y = x + 2 We can draw a graph of the function y = x + 2 by plotting points that obey this function.
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Drawing graphs of functions
Given a function, we can find coordinate points that obey the function by constructing a table of values. Suppose we want to plot points that obey the function y = x + 3 We can use a table as follows: x y = x +3 –3 –2 –1 1 2 3 Explain that when we construct a table of values, the value of y depends on the value of x. That means that we choose the values for x and substitute them into the equation to get the corresponding value for y. The minimum number of points needed to draw a straight line is two, however, it is best to plot several points to ensure that no mistakes have been made. The points given by the table can then be plotted to give the graph of the required function. 1 2 3 4 5 6 (–3, 0) (–2, 1) (–1, 2) (0, 3) (1, 4) (2, 5) (3, 6)
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Drawing graphs of functions
For example, to draw a graph of y = x – 2: y = x - 2 1) Complete a table of values: x y = x – 2 –3 –2 –1 1 2 3 –5 –4 –3 –2 –1 1 2) Plot the points on a coordinate grid. 3) Draw a line through the points. This slide summarizes the steps required to plot a graph using a table of values. 4) Label the line. 5) Check that other points on the line fit the rule.
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Drawing graphs of functions
Start by choosing a simple function. Remind pupils that we can draw graphs of functions by plotting inputs along the x-axis against outputs along the y-axis. Talk through the substitution of each value of x in the table and click to reveal the corresponding value of y below it. Start with the positive x-values, if required and work backwards along the table to include the negative values. Explain that each pair of values for x and y corresponds to a coordinate that we can plot on the coordinate axis. For example, for the equation y = 2x, when x = 1, y = 2. This corresponds to the coordinate (1,2). Click to plot each coordinate from the table of values onto the graph. Remind pupils that we always move along the x-axis and then up (or down) the y-axis when plotting coordinate points. A common mnemonic for this is ‘along the corridor and up the stairs’. Once all the points have been plotted ask pupils what they notice, that is that all the points lie in a straight line. Click ‘show line’ to draw a line through the points. Draw pupils attention to the fact that the line extends beyond either end of the points plotted on the graph. Use the crosshair button to find the coordinates of other points on the line.Verify that all of these points satisfy the equation. Ask pupils suggest other coordinates that would lie on this line. Establish that the line could be infinitely long and praise the most imaginative (correct!) answers.
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The equation of a straight line
The general equation of a straight line can be written as: y = mx + c The value of m tells us the gradient of the line. The value of c tells us where the line crosses the y-axis. Explain that the equation of a line can always be arranged to be in the form y = mx + c. It is often useful to have the equation of a line in this form because it tells us the gradient of the line and where it cuts the x-axis. These two facts alone can enable us to draw the line without have to set up a table of values. Ask pupils what they can deduce about two graphs that have the same value for m. Establish that if they have the same value for m, they will have the same gradient and will therefore be parallel. This is called the y-intercept and it has the coordinate (0, c). For example, the line y = 3x + 4 has a gradient of 3 and crosses the y-axis at the point (0, 4).
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Linear graphs with positive gradients
Use this activity to explore the effect of changing the value of the coefficient of x (m) and the value of the number that is added on (c). Start by keeping c set to 0 to explore graphs of the form y = mx. Establish that these graphs of this form: Are straight lines. Pass through the origin. Vary in steepness depending on the value of m. Ask pupils if they can explain why graphs of the form y = mx pass through the origin. Establish that at the origin the x-coordinate is equal to 0. Whatever we multiply 0 by, the answer is always 0. Therefore if x is 0, y is 0, regardless of the value of m, and the point (0, 0) is the origin. Next, explore graphs of the form y = x + c by keeping m set to 1 and changing the value of c. Establish that graphs of the form y = x + c: Have the same slope as y = x and so are parallel. Cut (or intersect) the y-axis at c, that is the point (0,c).
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Investigating straight-line graphs
Remind pupils that the the equation of a graph tells us the relationship between the x-coordinate and the y-coordinate of every point on that line. If the x- and y-coordinates of a point do not satisfy the equation of the line then the point cannot lie on the line. Also, the equation of a line represents an infinite set of points. A function is linear if the variables are not raised to any power other than 1 (not usually written). Investigating the gradient Ask a volunteer to drag the line on the board so that it has a gradient of 2. Point out that this means that for every square we move along the line we move two squares up. Add another line and ask another volunteer to drag the line to a different position and drag the end points to again produce a line with a gradient of 2. Ask pupils what they notice about the lines. Establish that lines with the same gradient are parallel. Look at the equation of each line. Ask pupils what they notice about the equations. Establish that the multiplier (the coefficient) of x is 2 for each line. The constant value that is added on in each case varies depending on where the line meets the vertical axis (the y-axis). All of the lines are of the form y = 2x + c, where c indicates where the line cuts the y-axis. Clear the lines from the graph. Drag the lines up and down to different positions to show that two parallel lines will always have the same coefficient for x. Repeat for different gradients. Investigating the y-intercept Define the y-intercept as the point where a line crosses the y-axis. Ask a volunteer to drag the line on the board so that it crosses the y-axis at the point (0, 2). State that the y-intercept of this line is 2. Add another line and ask another volunteer to drag the line and vary the gradient to produce another line with a y-intercept of 2. Reveal the equations of each line. Drag the end points of the lines to change the gradient, while keeping the the y-intercept fixed. Ask pupils what they notice about the equations of the lines, that is that all of the lines are of the form y = mx + 2. Conclude that the value of c tells us where the line cuts the y-axis. Clear the board and repeat, if required, with a different intercept, for example, -3. Note that, again, the multiplier (the coefficient) of x changes and the number that is added on the stays the same.
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The gradient and the y-intercept
Complete this table: equation gradient y-intercept y = 3x + 4 y = – 5 y = 2 – 3x 1 –2 3 (0, 4) x 2 1 2 (0, –5) (0, 2) –3 Complete this activity as a class exercise. (0, 0) y = x y = –2x – 7 (0, –7)
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Rearranging equations into the form y = mx + c
Sometimes the equation of a straight line graph is not given in the form y = mx + c. The equation of a straight line is 2y + x = 4. Find the gradient and the y-intercept of the line. We can rearrange the equation by transforming both sides in the same way 2y + x = 4 Explain that if the equation of a line is linear (that is if x and y are not raised to any power except 1), it can be arranged to be in the form y = mx + c. It is often useful to have the equation of a line in this form because it tells us the gradient of the line and where it cuts the y-axis. These two facts alone can enable us to draw the line without have to draw up a table of values. 2y = –x + 4 y = –x + 4 2 y = – x + 2 1 2
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Rearranging equations into the form y = mx + c
Sometimes the equation of a straight line graph is not given in the form y = mx + c. The equation of a straight line is 2y + x = 4. Find the gradient and the y-intercept of the line. Once the equation is in the form y = mx + c we can determine the value of the gradient and the y-intercept. Explain that the equation of a line can always be arranged to be in the form y=mx + c. It is often useful to have the equation of a line in this form because it tells us the gradient of the line and where it cuts the x-axis. These two facts alone can enable us to draw the line without have to draw up a table of values. y = – x + 2 1 2 1 2 – So the gradient of the line is and the y-intercept is 2.
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What is the equation? What is the equation of the line passing through the points Look at this diagram: C A B E G H F D 5 10 -5 a) A and E x = 2 b) A and F y = x + 6 c) B and E y = x – 2 d) C and D y = 2 Ask pupils to give you the equations of the lines passing through the required points by considering the gradient and the y-intercept of each line. Ask pupils to tell you which lines are parallel. Ask how we can use the equations of the lines to find out which ones are parallel. Establish, that parallel lines have the same gradient and therefore, the x’s have the same coefficient. e) E and G y = 2 – x f) A and C? y = 10 – x
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Substituting values into equations
A line with the equation y = mx + 5 passes through the point (3, 11). What is the value of m? To solve this problem we can substitute x = 3 and y = 11 into the equation y = mx + 5. This gives us: = 3m + 5 Subtracting 5: 6 = 3m Discuss ways to solve the problem. Some pupils may suggest plotting the point (3, 11) and drawing a straight line through this and the point (0, 5). The gradient of the resulting line will give the value for m. Ask pupils if they can suggest a method that does not involve drawing a graph. Establish that if the line passes through the point (3, 11) then we can substitute x = 3 and y = 11 into the equation y = mx + 5. Reveal the equation 11 = 3m + 5 on the board and talk through the steps leading to the solution of this equation. Dividing by 3: 2 = m m = 2 The equation of the line is therefore y = 2x + 5.
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Pairs Pupils take turn to choose two cards with the object of matching an equation to its corresponding graph. Each time a card showing a graph is revealed discuss possible equations for that graph. Each time an equation is revealed discuss the properties of the corresponding graph. The game can be played with the cards face up or face down.
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Matching statements Briefly discuss the graphs that would be produced by each of the equations on the left. Ask pupils what the gradient of each of the graphs would be and the y-intercept. Note: one of the graphs is not linear because it contains x-1 and does not, therefore, have a constant gradient. Discuss the fact that this graph never crosses the y-axis (x = 0) because when x = 0 we would be dividing by 0 which is undefined. Ask pupils to match each equation with the most appropriate statement by dragging matching pairs to fit together. Ask pupils to justify their choices with reference to the equation given.
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Exploring gradients Drag the end points of the line to demonstrate lines of varying gradient. (Notice that the gradient of a vertical line will appear as ‘undefined’ and the gradient of a horizontal line as 0). Show that the steeper the line is the larger the gradient. We can find the gradient by asking, For every unit we move horizontally (from left to right) how many squares do we move vertically (from bottom to top)? Demonstrate to pupils that when the line slopes downwards the change in the vertical distance is negative and so the gradient is negative. Define the gradient as ‘the vertical distance between the end points (from bottom to top) over the horizontal distance between the end points (from left to right) ‘. Show how the length of the line can be changed without changing the gradient by using equivalent fractions. For example, if the vertical distance between the end points is 6 and the horizontal distance between the end points is 4, the gradient of the line is 3/2. If we change the vertical distance to 9 and the horizontal distance to 6, the gradient of the line is still 3/2. Point out that it is most useful to write gradients as vulgar fractions. For example, the gradient 3/2 tells us that for every 2 squares we move along we move 3 up. Hide the value of the gradient and ask pupils to tell you the gradients of given lines. Include gradients that need to be cancelled down and negative gradients. Ask volunteers to come to the board and drag the end points of the line to give required gradients. For example, if you ask the volunteer to make a line with a gradient of –2 they could have the horizontal distance between the end points as 5 and the vertical distance between the end points as –10. Challenge another pupil to make the line longer (or shorter) without changing the gradient. Ask pupils to give you the coordinates of any two points on the line. Establish that the gradient can by found by dividing the difference between the y-coordinates by the difference between the x-coordinates.
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Gradients of straight-line graphs
The gradient of a line is a measure of how steep a line is. The gradient of a straight line y = mx + c is given by m = change in y change in x For any two points on a straight line, (x1, y1) and (x2, y2) Formally define the gradient as the change in y/the change in x. Explain that since, for a straight line, the change in y is proportional to the corresponding change in x, the gradient will be the same no matter which two points we choose on a line. m = y2 – y1 x2 – x1
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Contents A8 Linear and real-life graphs A A8.1 Linear graphs A
A8.2 Gradients and intercepts A A8.3 Parallel and perpendicular lines A A8.4 Interpreting real-life graphs A A8.5 Distance-time graphs A A8.6 Speed-time graphs
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Coordinate pairs (3, 5) (3, 5) (3, 5)
When we write a coordinate, for example, (3, 5) (3, 5) (3, 5) x-coordinate y-coordinate the first number is called the x-coordinate and the second number is called the y-coordinate. the first number is called the x-coordinate and the second number is the y-coordinate. Together, the x-coordinate and the y-coordinate are called a coordinate pair.
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Graphs parallel to the y-axis
What do these coordinate pairs have in common? (2, 3), (2, 1), (2, –2), (2, 4), (2, 0) and (2, –3)? The x-coordinate in each pair is equal to 2. Look what happens when these points are plotted on a graph. x y All of the points lie on a straight line parallel to the y-axis. Explain that as long as the x-coordinate is 2, the y-coordinate can be any number: positive, negative or decimal. Encourage pupils to be imaginative in their choice of points that lie on this line. For example, (2, ) (2, 43/78) or (2, – ). Name five other points that will lie on this line. This line is called x = 2. x = 2
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Graphs parallel to the y-axis
All graphs of the form x = c, where c is any number, will be parallel to the y-axis and will cut the x-axis at the point (c, 0). x y Stress that the graph of x = ‘a constant number’ will always be parallel to the y-axis. In other words, it will always be vertical. For each graph shown in the example, ask pupils to tell you the coordinate of the point where the line cuts the x-axis. Ask pupils to tell you the equation of the line that coincides with the y-axis (x = 0). x = –10 x = –3 x = 4 x = 9
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Graphs parallel to the x-axis
What do these coordinate pairs have in common? (0, 1), (4, 1), (–2, 1), (2, 1), (1, 1) and (–3, 1)? The y-coordinate in each pair is equal to 1. Look at what happens when these points are plotted on a graph. x y All of the points lie on a straight line parallel to the x-axis. y = 1 Explain that as long as the y-coordinate is 1 the x-coordinate can be any number: positive, negative or decimal. Encourage pupils to be imaginative in their choice of points that lie on this line. For example, ( , 1) (56/87, 1) or (– , 1). Name five other points that will lie on this line. This line is called y = 1.
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Graphs parallel to the x-axis
All graphs of the form y = c, where c is any number, will be parallel to the x-axis and will cut the y-axis at the point (0, c). x y y = 5 y = 3 Stress that the graph of y = ‘a constant number’ will always be parallel to the x-axis. In other words, it will always be horizontal. For each graph shown in the example, ask pupils to tell you the coordinate of the point where the line cuts the y-axis. Ask pupils to tell you the equation of the line that coincides with the x-axis (y = 0). y = –2 y = –5
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Plotting graphs of linear functions
The x-coordinate and the y-coordinate in a coordinate pair can be linked by a function. What do these coordinate pairs have in common? (1, –1), (4, 2), (–2, –4), (0, –2), (–1, –3) and (3.5, 1.5)? In each pair, the y-coordinate is 2 less than the x-coordinate. These coordinates are linked by the function: Ask pupils if they can visualize the shape that the graph will have. This might be easier if they consider the points (0, 2), (1, 3), (2, 4) (3, 5) etc. Establish the the points will lie on a straight diagonal line. Stress that the graphs of all linear functions are straight lines. A function is linear if the variables are not raised to any power (other than 1). Ask pupils to suggest the coordinates of any other points that will lie on this line. Look for imaginative answers. y = x – 2 We can draw a graph of the function y = x – 2 by plotting points that obey this function.
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Plotting graphs of linear functions
Given a function, we can find coordinate points that obey the function by constructing a table of values. Suppose we want to plot points that obey the function y = 2x + 5 We can use a table as follows: x y = 2x + 5 –3 –2 –1 1 2 3 Explain that when we construct a table of values, the value of y depends on the value of x. That means that we choose the values for x and substitute them into the equation to get the corresponding value for y. The minimum number of points needed to draw a straight line is two, however, it is best to plot several extra points to ensure that no mistakes have been made. The points given by the table can then be plotted to give the graph of the required function. –1 1 3 5 7 9 11 (–3, –1) (–2, 1) (–1, 3) (0, 5) (1, 7) (2, 9) (3, 11)
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Plotting graphs of linear functions
For example, y to draw a graph of y = 2x + 5: 1) Complete a table of values: x y = 2x + 5 –3 –2 –1 1 2 3 5 7 9 11 y = 2x + 5 2) Plot the points on a coordinate grid. 3) Draw a line through the points. This slide summarizes the steps required to plot a graph using a table of values. x 4) Label the line. 5) Check that other points on the line fit the rule.
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Plotting graphs of linear functions
Start by choosing a simple function. Remind pupils that we can draw graphs of functions by plotting inputs along the x-axis against outputs along the y-axis. Talk through the substitution of each value of x in the table and click to reveal the corresponding value of y below it. Start with the positive x-values, if required, and work backwards along the table to include the negative values. Explain that each pair of values for x and y corresponds to a coordinate that we can plot on the coordinate axis. For example, for the equation y = 2x, when x = 1, y = 2. This corresponds to the coordinate (1,2). Click to plot each coordinate from the table of values onto the graph. Remind pupils that we always move along the x-axis and then up (or down) the y-axis when plotting coordinate points. A common mnemonic for this is ‘along the corridor and up the stairs’. Once all the points have been plotted ask pupils what they notice, that is that all the points lie in a straight line. Click ‘show line’ to draw a line through the points. Draw pupils attention to the fact that the line extends beyond either end of the points plotted on the graph. Use the crosshair button to find the coordinates of other points on the line.Verify that all of these points satisfy the equation. Ask pupils to suggest other coordinates that would lie on this line. Establish that the line could be infinitely long and praise the most imaginative (correct) answers.
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A8.2 Gradients and intercepts
Contents A8 Linear and real-life graphs A A8.1 Linear graphs A A8.2 Gradients and intercepts A A8.3 Parallel and perpendicular lines A A8.4 Interpreting real-life graphs A A8.5 Distance-time graphs A A8.6 Speed-time graphs
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Gradients of straight-line graphs
The gradient of a line is a measure of how steep the line is. The gradient of a line can be positive, negative or zero if, moving from left to right, we have y x an upwards slope y x a horizontal line y x a downwards slope Positive gradient Zero gradient Negative gradient If a line is vertical, its gradient cannot be specified.
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Calculating gradients
By looking at a variety of examples, establish that if we are given the coordinates of any two points on a line we can find its gradient by taking the y-coordinate of the first point subtracted from the y-coordinate of the second point and diving it by the x-coordinate of the first point subtracted from the x-coordinate of the second point. Demonstrate to pupils that when the line slopes downwards the change in the vertical distance is negative as we move from left to right and so the gradient is negative. Show that choosing different points on the same line will give the same gradient using equivalent fractions. For example, if the vertical distance between the end points is 6 and the horizontal distance between the end points is 4, the gradient of the line is 3/2. If we change the vertical distance to 9 and the horizontal distance to 6, the gradient of the line is still 3/2. Point out that it is often most useful to leave gradients as improper fractions. For example, the gradient 3/2 tells us that for every 2 squares we move along we move 3 up. Hide the value of the gradient and ask pupils to tell you the gradients of given lines. Include gradients that need to be cancelled down and negative gradients. Ask volunteers to come to the board and vary the points to give lines of specified gradients. For example, if you ask the volunteer to make a line with a gradient of –2 they could have the horizontal distance between the end points as 5 and the vertical distance between the end points as –10.
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Finding the gradient from two given points
If we are given any two points (x1, y1) and (x2, y2) on a line we can calculate the gradient of the line as follows, y the gradient = change in y change in x x (x2, y2) y2 – y1 (x1, y1) Draw a right-angled triangle between the two points on the line as follows, x2 – x1 Explain how drawing a right-angled triangle on the line helps us calculate its gradient as shown in the previous activity. Explain too that since, for a straight line, the change in y is proportional to the corresponding change in x, the gradient will be the same no matter which two points we choose on a line. the gradient = y2 – y1 x2 – x1
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Investigating linear graphs
Use this activity to explore the effect of changing the value of the coefficient of x (m) and the value of the number that is added on (c). Establish that m is the gradient of the line and c is the intercept on the y-axis.
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The general equation of a straight line
The general equation of a straight line can be written as: y = mx + c The value of m tells us the gradient of the line. The value of c tells us where the line crosses the y-axis. Explain that the equation of a line can always be arranged to be in the form y = mx + c. It is often useful to have the equation of a line in this form because it tells us the gradient of the line and where it cuts the x-axis. These two facts alone can enable us to draw the line without having to set up a table of values. Ask pupils what they can deduce about two graphs that have the same value for m. Establish that if they have the same value for m, they will have the same gradient and will therefore be parallel. This is called the y-intercept and it has the coordinate (0, c). For example, the line y = 3x + 4 has a gradient of 3 and crosses the y-axis at the point (0, 4).
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The gradient and the y-intercept
Complete this table: equation gradient y-intercept y = 3x + 4 y = – 5 y = 2 – 3x 1 –2 3 (0, 4) x 2 1 2 (0, –5) (0, 2) –3 Complete this activity as a class exercise. (0, 0) y = x y = –2x – 7 (0, –7)
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Rearranging equations into the form y = mx + c
Sometimes the equation of a straight line graph is not given in the form y = mx + c. The equation of a straight line is 2y + x = 4. Find the gradient and the y-intercept of the line. Rearrange the equation by performing the same operations on both sides, 2y + x = 4 2y = –x + 4 subtract x from both sides: Explain that if the equation of a line is linear (that is if x and y are not raised to any power except 1), it can be arranged to be in the form y = mx + c. It is often useful to have the equation of a line in this form because it tells us the gradient of the line and where it cuts the y-axis. These two facts alone can enable us to draw the line without having to draw up a table of values. y = –x + 4 2 divide both sides by 2: y = – x + 2 1 2
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Rearranging equations into the form y = mx + c
Sometimes the equation of a straight line graph is not given in the form y = mx + c. The equation of a straight line is 2y + x = 4. Find the gradient and the y-intercept of the line. Once the equation is in the form y = mx + c we can determine the value of the gradient and the y-intercept. Explain that the equation of a (straight) line can always be arranged to be in the form y=mx + c. (This is not true for lines parallel to the y-axis.) It is often useful to have the equation of a line in this form because it tells us the gradient of the line and where it cuts the x-axis. These two facts alone can enable us to draw the line without having to draw up a table of values. y = – x + 2 1 2 1 2 – So the gradient of the line is and the y-intercept is (0, 2).
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Substituting values into equations
A line with the equation y = mx + 5 passes through the point (3, 11). What is the value of m? To solve this problem we can substitute x = 3 and y = 11 into the equation y = mx + 5. This gives us, = 3m + 5 subtract 5 from both sides: 6 = 3m Discuss ways to solve the problem. Some pupils may suggest plotting the point (3, 11) and drawing a straight line through this and the point (0, 5). The gradient of the resulting line will give the value for m. Ask pupils if they can suggest a method that does not involve drawing a graph. Establish that if the line passes through the point (3, 11) then we can substitute x = 3 and y = 11 into the equation y = mx + 5. Reveal the equation 11 = 3m + 5 on the board and talk through the steps leading to the solution of this equation. divide both sides by 3: 2 = m m = 2 The equation of the line is therefore y = 2x + 5.
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What is the equation of the line?
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Match the equations to the graphs
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A8.3 Parallel and perpendicular lines
Contents A8 Linear and real-life graphs A A8.1 Linear graphs A A8.2 Gradients and intercepts A A8.3 Parallel and perpendicular lines A A8.4 Interpreting real-life graphs A A8.5 Distance-time graphs A A8.6 Speed-time graphs
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Investigating parallel lines
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Parallel lines If two lines have the same gradient they are parallel.
Show that the lines 2y + 6x = 1 and y = –3x + 4 are parallel. We can show this by rearranging the first equation so that it is in the form y = mx + c. 2y + 6x = 1 2y = –6x + 1 subtract 6x from both sides: y = –6x + 1 2 divide both sides by 2: y = –3x + ½ The gradient m is –3 for both lines, so they are parallel.
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Matching parallel lines
There are two levels of difficulty for this activity. Level 1 shows all the line in the form y = mx + c. In level 2 some of the lines are not in the form y =mx + c, and these must be rearranged to find the value of m.
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Investigating perpendicular lines
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Perpendicular lines If the gradients of two lines have a product of –1 then they are perpendicular. In general, if the gradient of a line is m, then the gradient of the line perpendicular to it is –1 m Write down the equation of the line that is perpendicular to y = –4x + 3 and passes through the point (0, –5). The gradient of the line y = –4x + 3 is –4. 1 4 . The gradient of the line perpendicular to it is therefore 1 4 The equation of the line with gradient and y-intercept –5 is, y = x – 5 1 4
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Matching perpendicular lines
There are two levels of difficulty for this activity. Level 1 shows all the line in the form y = mx + c. In level 2 some of the lines are not in the form y = mx + c and these must be rearranged to find the value of m.
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