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Volumes Using Cross-Sections Solids of Revolution Solids Solids not generated by Revolution Examples: Classify the solids.

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Presentation on theme: "Volumes Using Cross-Sections Solids of Revolution Solids Solids not generated by Revolution Examples: Classify the solids."— Presentation transcript:

1 Volumes Using Cross-Sections Solids of Revolution Solids Solids not generated by Revolution Examples: Classify the solids

2 Volumes Using Cross-Sections Solids of Revolution Solids Solids not generated by Revolution

3 Volumes Using Cross-Sections Solids of Revolution Volumes Using Cross-Sections Volumes Using Cylindrical Shells Sec(6.2) Sec(6.1) The Disk Method The Washer Method

4 VOLUMES 1 The Disk Method Strip with small width generate a disk after the rotation

5 VOLUMES 1 The Disk Method Several disks with different radius r

6 VOLUMES

7 1 Disk cross-section x step1 Graph and Identify the region step2 Draw a line (L) perpendicular to the rotating line at the point x step4 Find the radius r of the circe in terms of x step5 Now the cross section Area is step6 Specify the values of x step7 The volume is given by Intersection point between L, rotating axis Intersection point between L, curve step3 Rotate this line. A circle is generated

8 VOLUMES

9

10 Volumes Using Cross-Sections Sec(6.1) The Disk Method The Washer Method

11 Volumes Using Cross-Sections Sec(6.1) The Disk Method The Washer Method Examples: Classify

12 Volumes Using Cross-Sections Sec(6.1) The Disk Method The Washer Method Examples: Classify

13 VOLUMES Volume = Area of the base X height

14 VOLUMES

15 If the cross-section is a washer,we find the inner radius and outer radius VOLUMES 2 The washer Method

16 VOLUMES step1 Graph and Identify the region step2 Draw a line perpendicular to the rotating line at the point x step4 Find the radius r(out) r(in) of the washer in terms of x step5 Now the cross section Area is step6 Specify the values of x step7 The volume is given by 2 The washer Method Intersec pt between L, rotation axis Intersection point between L, boundary step3 Rotate this line. Two circles created

17 VOLUMES T-102

18 Example: 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.

19 VOLUMES If the cross-section is a disk, we find the radius of the disk (in terms of y ) and use 3 The Disk Method (about y-axis)

20 VOLUMES The Disk Method (about y-axis) step1 Graph and Identify the region step2 Draw a line (L) perpendicular to the rotating line at the point y step4 Find the radius r of the circe in terms of y step5 Now the cross section Area is step6 Specify the values of y step7 The volume is given by step3 Rotate this line. A circle is generated

21 VOLUMES 4 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. The Washer Method (about y-axis or parallel)

22 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 step4 Find the radius r(out) r(in) of the washer in terms of y step5 Now the cross section Area is step6 Specify the values of y step7 The volume is given by step3 Rotate this line. Two circles created

23 solids of revolution 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

24 VOLUMES BY CYLINDRICAL SHELLS Remarks CYLINDRICAL SHELLS (6.2) rotating line Parallel to x-axis rotating line Parallel to y-axis Remarks Using Cross-Section(6.1) rotating line Parallel to x-axis rotating line Parallel to y-axis Cross-section is DISK Cross—section is WASHER SHELL Method

25 parallel to x-axis VOLUMES parallel to y-axis SHELLS Cross-Section

26 VOLUMES BY CYLINDRICAL SHELLS T-131 Remark: before you start solving the problem, read the choices to figure out which method you use

27 T-111

28 VOLUMES T-102

29 Volumes Using Cross-Sections Solids of Revolution Solids Solids not generated by Revolution

30 Volumes Using Cross-Sections The base of a solid is bounded by the curve y = x /2 and the line y =2. If the cross-sections of the solid perpendicular to the y-axis are squares, then find the volume of the solid Example: 2 Base: is bounded by the curve and the line y =2 If the cross-sections of the solid perpendicular to the y-axis are squares Cross-sections:

31 VOLUMES Jonathan Mitchell

32 VOLUMES The base of a solid is bounded by the curve and the line x =9. If the cross-sections of the solid perpendicular to the x-axis are semicircle, then find the volume of the solid Example: Base: is bounded by the curve and the line x =9 If the cross-sections of the solid perpendicular to the x-axis are semicircle Cross-sections:

33 VOLUMES The base of a solid is bounded by the curve and the line x =9. If the cross-sections of the solid perpendicular to the x-axis are semicircle, then find the volume of the solid Example: Base: is bounded by the curve and the line x =9 If the cross-sections of the solid perpendicular to the x-axis are semicircle Cross-sections:

34 VOLUMES The base of a solid is bounded by the curve and the line x =9. If the cross-sections of the solid perpendicular to the x-axis are semicircle, then find the volume of the solid Example: Base: is bounded by the curve and the line x =9 If the cross-sections of the solid perpendicular to the x-axis are semicircle Cross-sections:

35 VOLUMES The base of a solid is bounded by the curve and the line y = 0 from x=0 to x=pi. If the cross-sections of the solid perpendicular to the x-axis are equilatral triangles. Example: Base: is bounded by the curve and the line y =0 If the cross-sections of the solid perpendicular to the x-axis are semicircle Cross-sections:

36 VOLUMES The base of a solid is bounded by the curve and the line y = 0 from x=0 to x=pi. If the cross-sections of the solid perpendicular to the x-axis are equilatral triangles. Example: Base: is bounded by the curve and the line y =0 If the cross-sections of the solid perpendicular to the x-axis are equilatral triangles Cross-sections:

37 Volumes Using Cross-Sections The base of a solid is bounded by the curve y = x /2 and the line y =2. If the cross-sections of the solid perpendicular to the y-axis are squares, then find the volume of the solid Example: 2 If the cross-sections of the solid perpendicular to the y-axis are squares Cross-sections: step1 Graph and Identify the region ( graph with an angle) step2 Draw a line (L) perpendicular to the x-axis (or y-axis) at the point x (or y), (as given in the problem) step4 Cross-section type: Square  S = side length Semicircle  S = diameter Equilatral  S = side length step6 step7 The volume is given by step3 Find the length (S)of the segment from the two intersection points with the boundary step4 Cross-section type: Square  Semicircle  Equilatral  Specify the values of x

38 VOLUMES The base of a solid is bounded by the curve and the line x =9. If the cross-sections of the solid perpendicular to the x-axis are semicircle, then find the volume of the solid Example: If the cross-sections of the solid perpendicular to the x-axis are semicircle Cross-sections: step1 Graph and Identify the region ( graph with an angle) step2 Draw a line (L) perpendicular to the x-axis (or y-axis) at the point x (or y), (as given in the problem) step4 Cross-section type: Square  S = side length Semicircle  S = diameter Equilatral  S = side length step6 Specify the values of x step7 The volume is given by step3 Find the length (S)of the segment from the two intersection points with the boundary step4 Cross-section type: Square  Semicircle  Equilatral 

39 T-102 VOLUMES

40 T-122 VOLUMES

41 T-092 VOLUMES

42

43 T-132

44

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