Differentiation

1. Differentiation

2. Introduction • You will learn what Differentiation is • You will see how to apply it to solve graph based problems • It is one of the single most important topics there is in Maths!

3. Teachings for Exercise 7B

4. Differentiation You need to be able to find the gradient function of a formula On a straight line graph, the gradient is constant, the same everywhere along the line. On any curved graph, the gradient is always changing. Its value depends on where you are along the x-axis. The different gradients can be shown by tangents. These are lines that touch the curve in only one place. Differentiation is the process whereby we can find a formula to give the gradient on a curve, at any point on it. Straight Line = Constant Gradient tangent Curved line = Gradient Changes tangent 7B

5. Differentiation You need to be able to find the gradient function of a formula As a general rule, if; then… Examples Find the derived function of each of the following… a) f(x) = x3 f’(x) = 3x2 This is the formula for the curve, ie) the function b) f(x) = 2x2 f’(x) = 4x1 (4x) c) f(x) = x-2 This is the gradient function for f(x). The formula that gives the gradient at any point. Its is also know as the derivative, or ‘derived function’ f’(x) = -2x-3 d) f(x) = -3x-3 f’(x) = 9x-4 7B

6. Differentiation You need to be able to find the gradient function of a formula As a general rule, if; then… Examples Find the derived function of each of the following… e) Must be written in the form axn first! This is the formula for the curve, ie) the function This is the gradient function for f(x). The formula that gives the gradient at any point. Its is also know as the derivative, or ‘derived function’ f) Must be written in the form axn first! 7B

7. Teachings for Exercise 7C

8. Differentiation You need to be able to solve Graphical problems using the Gradient Function Remember that differentiating gives us a formula for the gradient at a given point on the graph (x). A standard question will ask you to work out the gradient of a curve at a particular point. This is when differentiating is used. Examples a) Calculate the gradient of the curve f(x) = x2 where x = 3 Differentiate to get the gradient function Substitute in the value for x at the required point b) Calculate the gradient of the curve f(x) = x2 at the coordinate (-2,4) y = x2 Differentiate to get the gradient function Substitute in the value for x at the required point 7C

9. Differentiation You need to be able to solve Graphical problems using the Gradient Function Remember that differentiating gives us a formula for the gradient at a given point on the graph (x). A standard question will ask you to work out the gradient of a curve at a particular point. This is when differentiating is used. Examples c) Find dy/dx when y equals x2 – 6x - 4 Differentiate each term separately. A number on its own disappears This also means the gradient function 7C

10. Differentiation You need to be able to solve Graphical problems using the Gradient Function Remember that differentiating gives us a formula for the gradient at a given point on the graph (x). A standard question will ask you to work out the gradient of a curve at a particular point. This is when differentiating is used. Examples d) Find dy/dx when y equals 3 – 5x2. Differentiate each term separately. A number on its own disappears 7C

11. Differentiation You need to be able to solve Graphical problems using the Gradient Function Remember that differentiating gives us a formula for the gradient at a given point on the graph (x). A standard question will ask you to work out the gradient of a curve at a particular point. This is when differentiating is used. Examples e) Let f(x) = 4x2 – 8x + 3. Find the gradient of the curve y = f(x) at the point (1/2, 0) Differentiate to get the gradient function Substitute in x = 1/2 7C

12. Differentiation You need to be able to solve Graphical problems using the Gradient Function Remember that differentiating gives us a formula for the gradient at a given point on the graph (x). A standard question will ask you to work out the gradient of a curve at a particular point. This is when differentiating is used. Examples f) Find the coordinates when the graph y = 2x2 - 5x + 3 has a gradient of 7. Differentiate to get the gradient function The gradient is 7 at the point we want Add 5 Divide by 4 The x coordinate where the gradient is 7 has a value of 3. Substitute this into the ORIGINAL function to find the y-coordinate So the graph has a gradient of 7 at (3,6) 7C

13. Differentiation You need to be able to solve Graphical problems using the Gradient Function Remember that differentiating gives us a formula for the gradient at a given point on the graph (x). A standard question will ask you to work out the gradient of a curve at a particular point. This is when differentiating is used. Examples g) Find the gradient of the curve y = x2 where it meets the line y = 4x - 3 Set the equations equal to each other (to represent where they meet) Group on the left Factorise The lines will meet at (3,9) and (1,1) by substitution. Differentiate y = x2 to get the gradient function At (3,9) the gradient will be 6 (by putting ‘3’ into the gradient function) At (1,1) the gradient will be 2 (by putting ‘1’ into the gradient function) 7C

14. Teachings for Exercise 7E

15. Differentiation You need to be able to deal with much more complicated equations when differentiating Remember as before, all terms must be written in the form axn before they can be differentiated. It is useful to note that at this stage, being able to rewrite in this way is not essential. However being able to switch between forms will be very useful on harder questions. Being able to do this now is worth practising as you will definitely need it on C2/3/4! Examples Differentiate the following: a) Rewrite in the form axn Differentiate Factorise 7E

16. Differentiation You need to be able to deal with much more complicated equations when differentiating Remember as before, all terms must be written in the form axn before they can be differentiated. It is useful to note that at this stage, being able to rewrite in this way is not essential. However being able to switch between forms will be very useful on harder questions. Being able to do this now is worth practising as you will definitely need it on C2/3/4! Examples Differentiate the following: b) Rewrite in the form axn Differentiate Imagine the term was split apart Rewrite the x term using power rules Group the fractions by multiplying tops/bottoms 7E

17. Differentiation You need to be able to deal with much more complicated equations when differentiating Remember as before, all terms must be written in the form axn before they can be differentiated. It is useful to note that at this stage, being able to rewrite in this way is not essential. However being able to switch between forms will be very useful on harder questions. Being able to do this now is worth practising as you will definitely need it on C2/3/4! Examples Differentiate the following: c) Split into 2 fractions Cancel x’s on the first one Rewrite in the form axn Differentiate Rewrite using power rules Make the Denominators common 7E

18. Teachings for Exercise 7F

19. Differentiation You can repeat the process of differentiation to get the ‘second order derivative’ Examples Original Equation Differentiate once (first order derivative) or Rewrite in the form axn Differentiate Differentiate again Differentiate twice (second order derivative) or 7F

20. Differentiation You can repeat the process of differentiation to get the ‘second order derivative’ Examples Original Equation Differentiate once (first order derivative) or Rewrite in the form axn Differentiate Differentiate twice (second order derivative) Differentiate again or 7F

21. Teachings for Exercise 7H

22. Differentiation You can use differentiation to find the tangent to a curve at a particular point, as well as the normal at that point Remember the curve we have is based on an equation The tangent is a straight line that intersects the curve at on point only. • The gradient of the tangent is the same as the gradient of the curve at the point given (so you can differentiate to get it) The ‘normal’ is a straight line perpendicular to the tangent where is touches the curve. Normal Curve Tangent 7H

23. Differentiation You can use differentiation to find the tangent to a curve at a particular point, as well as the normal at that point Find the equation of the tangent to the curve y = x3 – 3x2 + 2x - 1, at the point (3,5). So we need the gradient of the tangent. It will be the same as the gradient of the curve at the point given (x = 3) Differentiate to get the gradient function Substitute the x value in to find the gradient The gradient at (3,5) is 11 Use the formula for a straight line! Substitute the co-ordinate and gradient in Expand bracket Curve Add 5 Tangent 7H

24. Differentiation You can use differentiation to find the tangent to a curve at a particular point, as well as the normal at that point Find the equation of the normal to the curve y = 8 - 3√x at the point where x = 4. • Start by finding the gradient of the curve at that point. Gradient = -3/4 (this is of the tangent) The Normal is perpendicular to the tangent Gradient of the Normal = 4/3 Rewrite Differentiate Rewrite for substitution Sub in x = 4 The Gradient where x = 4 is -3/4 7H

25. Differentiation You can use differentiation to find the tangent to a curve at a particular point, as well as the normal at that point Find the equation of the normal to the curve y = 8 - 3√x at the point where x = 4. Gradient of the Normal = 4/3 Now we need the co-ordinates at that point. We already have x = 4. Co-ordinates at the intersection = (4,2) Substitute in x = 4 3 times 2 = 6! Use the formula for a straight line! Substitute the co-ordinate and gradient in Multiply by 3 Expand bracket Rearrange 7H

26. Differentiation y = x2 Showing how differentiation works (sort of!) Multiply the bracket This is a lowercase ‘delta’, representing a small increase in x Gradient = change in y ÷ change in x Group some terms Cancel δx (x+δx, (x+δx)2) (x+δx)2 – x2 At the original point, δx = 0 x+δx - x (x, x2)

27. Differentiation y = f(x) Showing how differentiation works (sort of!) Simplify the denominator This is a lowercase ‘delta’, representing a small increase in x Gradient = change in y ÷ change in x (x+δx, f(x+δx)) f(x+δx) – f(x) x+δx - x This is the ‘definition’ for differentiating a function (you won’t really need this specifically until C3) (x, f(x))

28. Summary • We have learnt what Differentiation is, and the process used • We have also seen the appropriate notation • We have also seen when to use it