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Let c (t) = (t 2 + 1, t 3 − 4t). Find: (a) An equation of the tangent line at t = 3 (b) The points where the tangent is horizontal. ` ` `

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Presentation on theme: "Let c (t) = (t 2 + 1, t 3 − 4t). Find: (a) An equation of the tangent line at t = 3 (b) The points where the tangent is horizontal. ` ` `"— Presentation transcript:

1 Let c (t) = (t 2 + 1, t 3 − 4t). Find: (a) An equation of the tangent line at t = 3 (b) The points where the tangent is horizontal. ` ` `

2 THEOREM 1 Arc Length Let c(t) = (x(t), y(t)), where x (t) and y (t) exist and are continuous. Then the arc length s of c(t) for a ≤ t ≤ b is equal to

3 The simplest parametrization of y = f (x) is c (t) = (t, f (t)). Which leads to the arc length formula derived in Section 9.1.

4 The arc length integral can be evaluated explicitly only in special cases. The circle and the cycloid are two such cases. Use THM 1 to calculate the arc length of a circle of radius R.

5 Calculate the length s of one arch of the cycloid generated by a circle of radius R = 2.

6 Speed is defined as the rate of change of distance traveled with respect to time, so by the 2 nd Fundamental Theorem of Calculus, THEOREM 2 Speed Along a Parametrized Path The speed of c (t) = (x (t), y (t)) is

7 The next example illustrates the difference between distance traveled along a path and displacement (also called net change in position). The displacement along a path is the distance between the initial point c (t 0 ) and the endpoint c (t 1 ). The distance traveled is greater than the displacement unless the particle happens to move in a straight line.

8 A particle travels along the path c (t) = (2t, 1 + t 3/2 ). Find: (a) The particle’s speed at t = 1 (assume units of meters and minutes).

9 A particle travels along the path c (t) = (2t, 1 + t 3/2 ). Find: (a) The particle’s speed at t = 1 (assume units of meters and minutes). (b) The distance traveled s and displacement d during the interval 0 ≤ t ≤ 4.

10 In physics, we often describe the path of a particle moving with constant speed along a circle of radius R in terms of a constant ω (lowercase Greek omega) as follows: c (t) = (R cos ωt, R sin ωt) The constant ω, called the angular velocity, is the rate of change with respect to time of the particle’s angle θ. A particle moving on a circle of radius R with angular velocity ω has speed |ω|R.

11 Angular Velocity Calculate the speed of the circular path of radius R and angular velocity ω. What is the speed if R = 3 m and ω = 4 rad/s? Thus, the speed is constant with value |ω|R. If R = 3 m and ω = 4 rad/s, then the speed is |ω|R = 3(4) = 12 m/s. c (t) = (R cos ωt, R sin ωt)

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