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Indefinite Integrals, Applications Section 6.1b. The set of all antiderivatives of a function is the indefinite integral of with respect to and is denoted.

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Presentation on theme: "Indefinite Integrals, Applications Section 6.1b. The set of all antiderivatives of a function is the indefinite integral of with respect to and is denoted."— Presentation transcript:

1 Indefinite Integrals, Applications Section 6.1b

2 The set of all antiderivatives of a function is the indefinite integral of with respect to and is denoted by Integral Sign Integrand Variable of Integration Also, recall that a function is an antiderivative of if Definition: Indefinite Integral

3 Then all antiderivatives of a function vary by constants: What keeps this integral from being “definite”??? The constant C is the constant of integration and is an arbitrary constant. When we find we have integrated or evaluated the integral…

4 Integral Formulas Indefinite IntegralReversed Derivative Formula 1. (a) (b) 2.

5 Integral Formulas Indefinite IntegralReversed Derivative Formula 3. 4. 5.

6 Integral Formulas Indefinite IntegralReversed Derivative Formula 6. 7. 8.

7 Using Integral Formulas Evaluate:

8 Properties of Indefinite Integrals Let k be a real number. 1. Constant Multiple Rule: If k = –1, then: 2. Sum and Difference Rule:

9 Integrating Term by Term Evaluate But we can simply combine all of these constants!!!

10 Do Now – p.314, #55 How long did it take the hammer and feather to fall 4 ft on the moon? Solve the following initial value problem for s as a function of t. Then find the value of t that makes s equal to 0. Differential equation: Initial conditions: and when Velocity:

11 Do Now – p.314, #55 How long did it take the hammer and feather to fall 4 ft on the moon? Solve the following initial value problem for s as a function of t. Then find the value of t that makes s equal to 0. Differential equation: Initial conditions: and when Position:

12 Do Now – p.314, #55 How long did it take the hammer and feather to fall 4 ft on the moon? Solve the following initial value problem for s as a function of t. Then find the value of t that makes s equal to 0. Differential equation: Initial conditions: and when Solving, we have Take the positive solution… They took about 1.240 seconds to fall

13 More Application Problems A right circular cylindrical tank with radius 5 ft and height 16 ft that was initially full of water is being drained at the rate of 0.5 x ft /min (x = water’s depth). Find a formula for the depth and the amount of water in the tank at any time t. How long will it take the tank to empty? 3 x Diff Eq:

14 More Application Problems A right circular cylindrical tank with radius 5 ft and height 16 ft that was initially full of water is being drained at the rate of 0.5 x ft /min (x = water’s depth). Find a formula for the depth and the amount of water in the tank at any time t. How long will it take the tank to empty? 3 Initial Condition: Solve Analytically: Diff Eq:

15 More Application Problems A right circular cylindrical tank with radius 5 ft and height 16 ft that was initially full of water is being drained at the rate of 0.5 x ft /min (x = water’s depth). Find a formula for the depth and the amount of water in the tank at any time t. How long will it take the tank to empty? 3 Solve Analytically: Initial Condition:

16 More Application Problems A right circular cylindrical tank with radius 5 ft and height 16 ft that was initially full of water is being drained at the rate of 0.5 x ft /min (x = water’s depth). Find a formula for the depth and the amount of water in the tank at any time t. How long will it take the tank to empty? 3 Equation for volume: At what t is V = 0?minutes (The tank will be empty in about 21 hours)

17 More Application Problems You are driving along a highway at a steady 60 mph (88 ft/sec) when you see an accident ahead and slam on the brakes. What constant deceleration is required to stop your car in 242 feet? First, solve the following initial value problem: Differential Equation:(k constant) Initial Conditions: andwhen Velocity: Solution:

18 More Application Problems You are driving along a highway at a steady 60 mph (88 ft/sec) when you see an accident ahead and slam on the brakes. What constant deceleration is required to stop your car in 242 feet? Next, find the value of t that makes ds/dt = 0: Velocity:Solution:

19 More Application Problems You are driving along a highway at a steady 60 mph (88 ft/sec) when you see an accident ahead and slam on the brakes. What constant deceleration is required to stop your car in 242 feet? Velocity:Solution: Finally, find the value of k that makes s = 242 for the previously found value of t : You would need to decelerate at this constant rate in order to stop in 242 feet!!!

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