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7.1 Integral As Net Change Quick Review What you’ll learn about Linear Motion Revisited General Strategy Consumption Over Time Net Change from Data.

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Presentation on theme: "7.1 Integral As Net Change Quick Review What you’ll learn about Linear Motion Revisited General Strategy Consumption Over Time Net Change from Data."— Presentation transcript:

1

2 7.1 Integral As Net Change

3 Quick Review

4 What you’ll learn about Linear Motion Revisited General Strategy Consumption Over Time Net Change from Data Work Essential Question How can the integral be used to calculate net change and total accumulation?

5 Example Linear Motion Revisited 1.v(t) = 10 – 2t is the velocity in m/sec of a particle moving along the x- axis when 0 < t < 9. Use analytical methods to: a.Determine when the particle is moving to the right, to the left, and stopped. b.Find the particle’s displacement for the given time interval. c.If s(0) = 3, what is the particle’s final position? d.Find the total distance traveled by the particle.

6 Example Linear Motion Revisited 1.v(t) = 10 – 2t is the velocity in m/sec of a particle moving along the x- axis when 0 < t < 9. Use analytical methods to: b.Find the particle’s displacement for the given time interval. It moves 9 units to the right in the first 9 seconds.

7 Example Linear Motion Revisited 1.v(t) = 10 – 2t is the velocity in m/sec of a particle moving along the x- axis when 0 < t < 9. Use analytical methods to: c.If s(0) = 3, what is the particle’s final position? Which is the original position of 3 plus displacement of 9.

8 Example Linear Motion Revisited 1.v(t) = 10 – 2t is the velocity in m/sec of a particle moving along the x- axis when 0 < t < 9. Use analytical methods to: d.Find the total distance traveled by the particle. Total distance is 41 m.

9 Strategy for Modeling with Integrals 1.Approximate what you want to find as a Riemann sum of values of a continuous function multiplied by interval lengths. If f (x) is the function and [a, b] the interval, and you partition the interval into subintervals of length  x, the approximating sums will have the form a point in the kth subinterval. 2.Write a definite integral, here to express the limit of these sums as the norm of the partitions go to zero. 3.Evaluate the integral numerically or with an antiderivative.

10 Example Potato Consumption 2.From 1970 to 1980, the ratio of potato consumption in a particular country was C(t) = 2.2 + 1.1 t million of bushels per year, with t being years since the beginning of 1970. How many bushels were consumed from the beginning of 1972 to the end of 1975? Step 1: Riemann sum We partition [2, 6] into subintervals of length  t and let t k be a time in the kth subinterval. The amount consumed during this subinterval is approximately C (t k )  t million bushels. The consumption for [2, 6] is approximately  C (t k )  t million bushels.

11 Example Potato Consumption 2.From 1970 to 1980, the ratio of potato consumption in a particular country was C(t) = 2.2 + 1.1 t million of bushels per year, with t being years since the beginning of 1970. How many bushels were consumed from the beginning of 1972 to the end of 1975? Step 2: Definite Integral The amount consumed from t = 2 to t = 6 is the limit of these sums as the norms of the partitions go to zero. Step 3: Evaluate Evaluate numerically, we obtain: mil bushels

12 Work When a body moves a distance d along a straight line as a result of the action of a force of constant magnitude F in the direction of motion, the work done by the force is The equation W = Fd is the constant – force formula for work. The units of work are force x distance. In the metric system, the unit is the newton – meter or joule. In the U.S. customary system, the most common unit is the foot – pound. Hooke’s Law for springs says that the force it takes to stretch or compress a spring x units from its natural length is a constant times x. In symbols: F = kx, where k, measured in force units per length, is a force constant.

13 Example A Bit of Work 3.It takes a force of 6N to stretch a spring 2 m beyond its natural length. How much work is done in stretching the spring 5 m from its natural length? By Hooke’s Law, F(x) = kx. Therefore k = F(x) / x. Step 1: Riemann sum We partition [0, 5] into subintervals of length  x and let x k be any point in the kth subinterval. The work done across the interval is approximately F (x k )  x. The sum for [0, 5] is approximately  F (x k )  x =  3x k  x. Step 2 and 3: Evaluate Definite Integral

14 Pg. 386, 7.1 #1-29 odd

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