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What if we wanted the area enclosed by:

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Presentation on theme: "What if we wanted the area enclosed by:"— Presentation transcript:

1 What if we wanted the area enclosed by:
Or the slope of this tangent line?

2 Let’s start with the slope which for any curve is equal to
But how does one find this in relation to polar functions? Here’s what we know: How? Product Rule, of course

3 To find the slope of a polar curve:

4 Find the slope of this tangent line at

5 Find the equation of this tangent line at

6 Find the equation of this tangent line at

7 What about the area enclosed by:
Start with this slice

8 What about the area enclosed by:
This slice is approximately the shape of an isosceles triangle The area requires that we know height and base. Remember arclength from trig? where  must be in radians In this case, the angle is very small so we will call it d So the area of this slice can be approximated as

9 What about the area enclosed by:
To extend this approximation over the whole region we will need an… Integral I knew you wouldn’t forget  and  are usually 0 and 2p but it depends upon the problem

10 Now find the area… Example: Find the area enclosed by:

11

12 The shaded region to the right is bounded by the polar curves:
But what about this one? The shaded region to the right is bounded by the polar curves: and Find the area of the shaded region. We need to find  and . So we need to set the two curves equal to each other.

13 To find the area between curves, subtract:
Just like finding the areas between Cartesian curves, establish limits of integration where the curves cross.

14 Using Symmetry Area of one leaf times 4: Area of four leaves:

15 p To find the length of a curve: Remember: For polar graphs:
If we find derivatives and plug them into the formula, we (eventually) get: So: p

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