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Differentials Intro The device on the first slide is called a micrometer….it is used for making precision measurements of the size of various objects…..a.

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Presentation on theme: "Differentials Intro The device on the first slide is called a micrometer….it is used for making precision measurements of the size of various objects…..a."— Presentation transcript:

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4 Intro The device on the first slide is called a micrometer….it is used for making precision measurements of the size of various objects…..a small metal cube, the diameter of a ball bearing, etc…. However, even a precision instrument like a micrometer has an error in measuring things….

5 Errors in measurement, like a small error in the diameter of a ball bearing, can lead to major problems in an engine, if the ball bearing’s size is too far off from it’s allowed variation.

6 To measure the precise change in a mathematical function, such as a change in an equation, we use Δy, the change in y. But this can be messy to calculate ……. it would be nice to use a simpler way to represent the change in y, and using Calculus, we can !!!

7 After this lesson, you should be able to: Understand the concept of a tangent line approximation. Compare the value of the differential, dy, with the actual change in y, Δy. Estimate a propagated error using a differential. Find the differential of a function using differentiation formulas.

8 A Simple Example Differentials Let S ( x ) be the area of a square of side length x. Or, Now we give the side a change Δx, then the corresponding change of area will be S ( x ) = x 2 ΔS = S ( x + Δx ) – S ( x ) = ( x + Δx ) 2 – x 2 = 2 xΔx + ( Δx ) 2 ΔxΔx ΔxΔx x x xΔxxΔx xΔxxΔx (Δx)2(Δx)2 Compare with Δx, ( Δx) 2 is the infinite smaller change. Or,

9 A Simple Example Differentials ΔxΔx ΔxΔx x x xΔxxΔx xΔxxΔx (Δx)2(Δx)2 For any function of g ( Δx ), if We call g ( Δx ) is higher order of infinitesimal of Δx, denoted as ε ( Δx ). In other words, the change of area can be approximated to the first part of ΔS = S ( x + Δx ) – S ( x ) = 2 xΔx + ε ( Δx )= 2 xΔx + ( Δx ) 2 The first part above is linear to Δx. We call the first part as “Linear Principal Part ”.

10 Find the equation of the line tangent to at (1,1). Try This (1,1)

11 Analysis (1,1) x 0.91.01.1 f(x) y Complete the table

12 Analysis (1,1) x 0.91.01.1 f(x).81 11.21 y.8 11.2 Complete the table

13 Linear Approximation to a Function Linear Approximation or TANGENT LINE!!!!!

14 Important Idea The equation of the line tangent to f(x) at c can be used to approximate values of f(x) near f(c).

15 Definition of Differentials

16 y = f(x) = x 2 y = 2 x + 1 ΔxΔx dy ΔyΔy ε(Δx)ε(Δx) In many types of application, the differential of y can be used as an approximation of the change of y. or (1,1) f(x+Δx) f(x)f(x)

17 Animated Graphical View Note how the "del y" and the dy in the figure get closer and closer

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28 Example 1 Find dy for f (x) = x 2 + 3x and evaluate dy for x = 2 and dx = 0.1.

29 Example 1 Find dy for f (x) = x 2 + 3x and evaluate dy for x = 2 and dx = 0.1. Solution: dy = f ’(x) dx = (2x + 3) dx When x = 2 and dx = 0.1, dy = [2(2) + 3] 0.1 = 0.7.

30 Derivatives in differential form Function derivative differential y = x n y ’ = n x n-1 dy = n x n-1 dx y = UV y ′ = UV ′ + VU ′ dy = U dV + V dU y = U y ’ = V U ′ – U V ′ dy = V dU – U dV V V 2 V 2

31 Finding Differentials FunctionDerivativeDifferential y = x 2 y = 2 sin x y = x cosx

32 Finding Differentials FunctionDerivativeDifferential y = x 2 y = 2 sin x y = x cosx

33 Finding Differentials FunctionDerivativeDifferential y = x 2 y = 2 sin x y = x cosx

34 Finding Differentials FunctionDerivativeDifferential y = x 2 y = 2 sin x y = x cosx

35 Finding Differentials FunctionDerivativeDifferential y = x 2 y = 2 sin x y = x cosx

36 Finding Differentials FunctionDerivativeDifferential y = x 2 y = 2 sin x y = x cosx

37 Finding Differentials FunctionDerivativeDifferential y = x 2 y = 2 sin x y = x cosx

38 Try This Find the differential dy of the function:

39 Linear Approximation to a Function Linear Approximation or TANGENT LINE!!!!!

40 Find the tangent line approximation of at the point (0,1).

41 Find the tangent line approximation of at the point (0,1).

42 Example Solution Let’s consider the function and set x = 1, Δx = 0.02, then Example 1 Find the approximate value of the cubic root

43 Example Solution Practice Find the approximate value of square root Let’s consider the function and set x = 49, Δx = –0.02, then

44 Example 1 Estimate ( 64.3 ) 1/3 Let y = ( x ) 1/3. 64.3 = 64 + 0.3 Let x = 64 and Δ x = 0.3 = 3/10 So y + Δ y ≈ y + dy and dy = 1/3 x – 2/3 dx y + dy = ( 64 ) 1/3 + 1/3 ( 64 ) -2/3 ( 3/10 ) = 4 + 1/3 ( 1/16 ) ( 3/ 10 )

45 = 4 + 1 / 160 = 4 = 4.00625 1 160 ( 64.3 ) 1/3 = 4.00624026 By calculator, ( 64.3 ) 1/3 = 4.00624026 Not bad….considering they had no calculator back then !!!

46 Error Propagation Physicists and engineers tend to make liberal use of the approximation of Δy by dy. One way this occrus in practice is in the estimation of errors propagated by physical measuring devices. x – measured value of a variable x + Δx – the exact value Δx – the error in measurement f(x + Δx) – f ( x ) = Δy Measurement Error Measured Value Exact Value Propagated Error If the measured value x is used to compute another value f ( x ), then

47 Propagated Error Consider a rectangular box with a square base –Height is 2 times length of sides of base –Given that x = 3.5 –You are able to measure with 3% accuracy What is the error propagated for the volume? x x 2x

48 Propagated Error We know that Then dy = 6x 2 dx = 6 * 3.5 2 * 0.105 = 7.7175 This is the approximate propagated error for the volume

49 Propagated Error The propagated error is the dy –sometimes called the df The relative error is The percentage of error – relative error * 100%

50 Example Solution It is obvious that from the given information r = 6 inches and Δr = dr = ±0.02 inches Example 2 The radius of a sphere is measured to be 6 inches, with a possible error of 0.02 inch. Use differentials to approximate the maximum possible error in calculating (a)The volume of the sphere (b)The surface area of the sphere (c)The relative errors in parts (a) and (b) (a) in 3

51 Example Solution It is obvious that from the given information r = 6 inches and Δr = dr = ±0.02 inches Example 2 The radius of a sphere is measured to be 6 inches, with a possible error of 0.02 inch. Use differentials to approximate the maximum possible error in calculating (a)The volume of the sphere (b)The surface area of the sphere (c)The relative errors in parts (a) and (b) (b) in 2

52 Example Solution Example 2 The radius of a sphere is measured to be 6 inches, with a possible error of 0.02 inch. Use differentials to approximate the maximum possible error in calculating (a)The volume of the sphere (b)The surface area of the sphere (c)The relative errors in parts (a) and (b) (c)

53 Calculating Differentials The differentiation rules we learned in Chapter 2 can be migrate to here Constant Multiple Sum or Difference Product Quotient

54 Calculating Differentials Don’t forget the chain rule in calculating the derivatives. The same rule is true in calculating the differentials

55 Example Example 3 Find the differentials Solution

56 Example Example 4 Find the differentials Solution

57 Example Example 5 Find the differentials Solution

58 Example Example 6 Find the differential dy in an implicit function if y is a function of x and Solution

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