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6.2C Volumes by Slicing with Known Cross-Sections.

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Presentation on theme: "6.2C Volumes by Slicing with Known Cross-Sections."— Presentation transcript:

1 6.2C Volumes by Slicing with Known Cross-Sections

2 Known Cross Sections Method
Volume can be calculated by finding area of known geometric shapes and multiplying by thickness (dx). Here is an example of squares stacked on top of a circular region.

3 Visualizations Rectangular Cross-Sections Semicircular Cross-Sections
Equilateral Triangle Cross-Sections

4 We can find the area of each cross section, then add an infinite number of infinitely thin cross sections. When we multiply by thickness, we have volume.

5 Examples Cross sections may be rectangles, semi-circles or triangles. The base of the solid may be a rectangle, circle, triangle or an irregular shape. Mathematica

6 Method of Slicing: 1 Sketch the base of the solid (including a typical slice) and a typical cross section. Find a formula for A(x) and multiply by dx for width. 2 3 Find the limits of integration. 4 Integrate V(x) to find volume.

7 Find the volume of the solid whose base is bounded by the circle x2+y2=4 with square cross sections perpendicular to the x-axis. y x 422/51(c)

8 Find the volume of the solid whose base is bounded by the circle x2+y2=4 with semicircular cross sections perpendicular to the x-axis y x 422/51(c)

9 Find the volume of the solid whose base is bounded by the circle x2+y2=4 with equilateral triangle cross sections perpendicular to the x-axis. x y

10 Find the volume of the solid formed with the region defined by and
as the base and cross sections that are squares perpendicular to the base and the x-axis. 81/10 sq units

11 3 Find the volume of the pyramid: Consider a horizontal slice through the pyramid. The volume of the slice is s2dh. If we put zero at the top of the pyramid and make down the positive direction, then s=h. h s This correlates with the formula: dh 3

12 p Cavalieri’s Theorem:
Two solids with equal altitudes and identical parallel cross sections have the same volume. Identical Cross Sections p

13 Ex. Find the volume of the solid whose base is a circle of radius 1 in the first quadrant and with square cross-sections  x-axis.

14 Ex. Find the volume of the solid whose base is bounded by the x-axis, the y-axis, x = 9, and with semi-circular cross-sections  x-axis.

15 Find the volume of the solid whose base is a circle of radius 1 centered at the origin and with isosceles right triangles cross-sections  x-axis.

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