Calculus Applications of Differentiation. Norhafizah Md Sarif Faculty of Industrial Science & Technology

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Calculus Applications of Differentiation By Norhafizah Md Sarif Faculty of Industrial Science & Technology norhafizah@ump.edu.my

Description Aims This chapter is aimed to : 1. introduce the concept of integration. evaluate the definite and indefinite integral 3. explain the basic properties of integral 4. compute the integral using different techniques of integration Expected Outcomes 1. Students should be able to describe the concept of antiderivatives. Students should be able to explain about indefinite integral and definite integral 3. Students should be able to know the basic properties of definite integrals 4. Student should be able to determine the appropriate techniques to solve difficult integral. References 1. Abdul Wahid Md Raji, Hamisan Rahmat, Ismail Kamis, Mohd Nor Mohamad, Ong Chee Tiong. The First Course of Calculus for Science & Engineering Students, Second Edition, UTM 016.

Content 1 3 Curve Slope at One Point Rate of Change Maximum and Minimum

Applications of Differentiation 1 Curve/ Slope Max & Min Points 3 Related Rates

Curve Slope at a Point

The gradient curve at a point can be defined as the gradient of tangent line at the point of the curve. Assume that PT is a tangent to the curve at P. Let P be a point moving along the curve AB. When P is moving from A to B, the tangent to the curve is also moving. In other words, the gradient of the tangent to the curve is changing and it can be obtained by substituting the coordinate points in or. y P T 4

Example Find the slope for the curve y x 3x 4 at point (3,14) Differentiate y with respect to x dy x 3 dx When x 3 dy 3 3 9 dx Thus the slope for the curve y x x 3 4 at point is 9.

Example 4 Find the slope for the curve y x at point (1,5) x Differentiate y with respect to x When x 1 at dy dx 1 4 x dy 4 1 3 dx 1 The slope for the curve is 3. Negative sign indicates the slope is decreasing when x 1.

Example 4x x Find the slope for the curve y at x. x 1 Using quotient rule, u x x v x 4 1 u 8x 1 v dy x x dx x 1 When x 8 8 3 dy dx 8(4) 16 3 13 3 9 Thus the slope for the curve y 4x x x 1 at point is 13 9.

Example Find the equation of tangent line for the curve x 4xy y 3 at (-,1). Differentiate using implicit differentiation, we obtain y 4x dy 4y x dx Slope of the tangent at point (,1) dy dx (, 1) 4(1) ( ) 4 (1) 4( ) 5 Equation of tangent line at (-,1) is given by 4 y1 ( x ) 5 5y4x13

Example The parametric equations of a curve given 1 1 x t, y t where t 0 t t Find the coordinates of the points on the curve where its gradient is zero and also find the tangent equation at t. Differentiate the parametric equation dx 1 dy 1 1, 1 dt t dt t Slope of the tangent at point is zero, thus dy dx t 1 0 t 1 t 1

The coordinates of the points are (0,) and (0,-) when t 1 1 t 1: x 1 0, y 1, 1 1 1 1 t 1: x 1 0, y 1 1 1 1 3 1 5 t : x, y, dy 1 3 dx t 1 5 Equation of tangent is given by 5 3 3 y ( x ) 5 5y3x8

Rates of Change If is a function of, then is the change of changes with respect to. When represents time, then we usually use the symbol. In which case is a measure of the rate of change in. For example, if represents the radius of a circle in meters and represents time in seconds, then represents the rate of change of radius. The chain rule, is sometime used in solving problems involving rates of change. Other than that, implicit differentiation can also be applied to solve related rates and will gives fastest results.

Procedure for solving rate of change problems: 1 List all the given quantities, rewrite problems using mathematical notations Use equation that relate with the changing quantities. Take derivative to get the relating rates 3 Solve by using chain rule or implicit differentiation.

Example Circle The radius of a circle is increasing at a rate of 10 cm/s. How fast is the area is increasing at the instant when the radius has reached 5 cm? [ area of circle = πr ] 14

Given, Find da dt dr 10cm/s dt when r 5 cm 1. From to r A r, differentiate with respect and substitute value when 5 r cm. da r 5 10 dr Applying chain rule, da da dr dt dr dt 10 cm 10 cm/s =314 cm /s 3. The area of circle increase at rate 314 cm /s.

Example Spherical A spherical balloon is inflated with air at the rate of 00cm 3 /s. Find the rate of change of the radius of the balloon when the radius is 6cm. Volume of sphere = 4/3πr 3 ] 17

Given, Find dr dt when From V to r dv 3 00cm /s dt 4 3 r 6 cm 3 r, differentiate with respect and substitute value when 6 dv dr 4 r 4 6 144 Applying chain rule, dv dv dr dt dr dt 00 144 dr dt =0.441 Method 1: Chain Rule dr dt r cm From V Method : Implicit 4 3 3 r, differentiate by using implicit differentiation dv dt d 4 dt 3 dr 4 3 r r dt Substitute value when dv dt d 4 dt 3 3 r 00 4 (6) dr dt 0.441 dr dt r 6 cm 18

Example Cylindrical A cylindrical tank has a base with radius, r = m. The tank is filled with water at the rate of m 3 /min. Find the rate of change of the water level in the tank. [ Volume of a cylinder = πr h] 0

Example Cone A tank of water in the shape of a cone is leaking water at a constant rate of m 3 /hour. The base radius of the tank is 5m and the height of the tank is 14m. [ Volume of a cone = 1/3 πr h] (a) At what rate is the depth of the water in the tank changing when the depth of the water is 6m? (b) At what rate is the radius of the top of the water in the tank changing when the depth of the water is 6m?

Example Motion A body moves along a straight line according to the law, 1 3 s t t. Determine its velocity and acceleration after. s

Example When a ball is thrown straight-up in the air, its position may be measured as the vertical distance from the ground. Regards up as the positive direction, and let feet after t second, suppose that (a) What is the velocity after s st () s t t t ( ) 16 18 5 (b) What is the acceleration after s? (c) At what time is the velocity -3m/s? (d) When is the ball at height of 117m? be the height of the ball in

Example A 15m ladder is resting against the wall. The bottom is initially 10m away from the wall and is being pushed towards the wall at a rate of ¼ m/s. How fast is the top of the ladder moving up the wall if the bottom of the ladder is 7m away from the wall? 4

Example Two people are 50m apart. One of them starts walking north at a rate so that the angle shown in the diagram below is changing at a constant rate of 0.01rad/min. At what rate is distance between the two people changing when θ = 0.5rad? 5

Conclusion In integration by substitution, making appropriate choices for u will come with experience. Selecting u for by part techniques should follow the LATE guideline. If the power of denominator is less than the power of numerator, then the fraction is called proper fraction

Author Information Norhafizah Binti Md Sarif Lecturer Faculty of Industrial Sciences & Technology (website) Universiti Malaysia Pahang Email: norhafizah@ump.edu.my Google Scholar: : Norhafizah Md Sarif Scopus ID : 571905369 UmpIR ID: 3479

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