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Sec 6.2: VOLUMES Volume = Area of the base X height.

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Presentation on theme: "Sec 6.2: VOLUMES Volume = Area of the base X height."— Presentation transcript:

1 Sec 6.2: VOLUMES Volume = Area of the base X height

2 Sec 6.2: VOLUMES Volume = Area of the base X height

3 Sec 6.2: VOLUMES For a solid S that isn’t a cylinder we first “cut” S into pieces and approximate each piece by a cylinder.

4 Sec 6.2: VOLUMES

5 If the cross-section is a disk, we find the radius of the disk (in terms of x ) and use 1 Disk cross-section x animation

6 Sec 6.2: VOLUMES 1 Disk cross-section x use your imagination

7 Sec 6.2: VOLUMES 1 Disk cross-section x use your imagination

8 Sec 6.2: VOLUMES 1 Disk cross-section x step1 Graph and Identify the region step2 Draw a line perpendicular to the rotating line at the point x step3 Find the radius r of the disk in terms of x step4 Now the cross section Area is step5 Specify the values of x step6 The volume is given by

9 Sec 6.2: VOLUMES

10

11 If the cross-section is a washer,we find the inner radius and outer radius Sec 6.2: VOLUMES 2 washer cross-section x

12 Sec 6.2: VOLUMES step1 Graph and Identify the region step2 Draw a line perpendicular to the rotating line at the point x step3 Find the radius r(out) r(in) of the washer in terms of x step4 Now the cross section Area is step5 Specify the values of x step6 The volume is given by 2 washer cross-section x

13 Sec 6.2: VOLUMES T-102

14 Example: Sec 6.2: VOLUMES Find the volume of the solid obtained by rotating the region enclosed by the curves y=x and y=x^2 about the line y=2. Find the volume of the resulting solid.

15 Sec 6.2: VOLUMES If the cross-section is a disk, we find the radius of the disk (in terms of y ) and use 3 Disk cross-section y

16 Sec 6.2: VOLUMES 3 Disk cross-section y step1 Graph and Identify the region step2 Draw a line perpendicular to the rotating line at the point y step3 Find the radius r of the disk in terms of y step4 Now the cross section Area is step5 Specify the values of y step6 The volume is given by step2 Rewrite all curves as x = in terms of y

17 If the cross-section is a washer,we find the inner radius and outer radius Sec 6.2: VOLUMES 4 washer cross-section y Example: The region enclosed by the curves y=x and y=x^2 is rotated about the line x=-1. Find the volume of the resulting solid.

18 Sec 6.2: VOLUMES 4 washer cross-section y step1 Graph and Identify the region step2 Draw a line perpendicular to the rotating line at the point y step3 Find the radius r(out) and r(in) of the washer in terms of y step4 Now the cross section Area is step5 Specify the values of y step6 The volume is given by step2 Rewrite all curves as x = in terms of y

19 Sec 6.2: VOLUMES T-091

20 Sec 6.2: VOLUMES T-072

21 If the cross-section is a washer,we find the inner radius and outer radius Sec 6.2: VOLUMES 4 washer cross-section y T-102

22 solids of revolution Sec 6.2: VOLUMES SUMMARY: The solids in all previous examples are all called solids of revolution because they are obtained by revolving a region about a line. Rotated by a line parallel to x-axis ( y=c) Rotated by a line parallel to y-axis ( x=c) NOTE: The cross section is perpendicular to the rotating line solids of revolution Cross-section is DISK Cross—section is WASHER

23 Sec 6.2: VOLUMES not solids of revolution The solids in all previous examples are all called solids of revolution because they are obtained by revolving a region about a line. We now consider the volumes of solids that are not solids of revolution.

24 T-102 Sec 6.2: VOLUMES

25 T-092 Sec 6.2: VOLUMES

26

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