6: Geometry

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6.1: Perimeter and Circumference
This page explains the concepts of perimeter and circumference in geometry, defining polygons and detailing how to calculate their perimeter through side lengths, with specific formulas for shapes like squares and rectangles. It distinguishes circumference from perimeter for circles and includes relevant formulas involving pi. The page also features exercises for practice, along with answers for verification.
6.2: Area of Polygons and Circles
We have seen that the perimeter of a polygon is the distance around the outside. Perimeter is a length, which is one-dimensional, and so it is measured in linear units (feet, centimeters, miles, etc.). The area of a polygon is the amount of two-dimensional space inside the polygon, and it is measured in square units: square feet, square centimeters, square miles, etc.
6.3: Composite Figures
Many objects have odd shapes made up of simpler shapes. A composite figure is a geometric figure which is formed by—or composed of—two or more basic geometric figures. We will look at a handful of fairly simple examples, but this concept can of course be extended to much more complicated figures.
6.4: Surface Area of Common Solids
This page covers the surface areas of three-dimensional solids, highlighting the difference between lateral surface area (LSA) and total surface area (TSA) using examples like rectangular solids, cylinders, and spheres. It explains that LSA for rectangular solids excludes top and bottom faces, while TSA includes all faces, with similar principles for cylinders. Spheres only have TSA due to their lack of faces.
6.5: Volume of Common Solids
The surface area of a solid is the sum of the areas of all its faces; therefore, surface area is two-dimensional and measured in square units. The volume is the amount of space inside the solid. Volume is three-dimensional, measured in cubic units. You can imagine the volume as the number of cubes required to completely fill up the solid.
6.6: Pyramids and Cones
This page covers the geometry of pyramids and cones, detailing their volume and surface area calculations. It defines pyramids by their polygonal bases and triangular faces, and cones by their circular base. The formulas show that pyramids and cones have one-third the volume of their corresponding prisms and cylinders. Exercises focus on calculating volume and surface areas, and a practical exercise involves calculating the volume of a propane tank.

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