Frustum Calculator
Calculate volume and surface area of a frustum (truncated cone or pyramid). Enter values for instant results with step-by-step formulas.
Formula
V = (pi h / 3)(R^2 + Rr + r^2) | Lateral Area = pi(R + r) x slant height
Where V = volume, h = perpendicular height of the frustum, R = radius of the larger base, r = radius of the smaller base, and slant height = sqrt(h^2 + (R-r)^2). For a square pyramid frustum, replace circular areas and perimeters with square equivalents.
Worked Examples
Example 1: Bucket Volume Calculation
Problem: A bucket has a bottom radius of 12 cm, top radius of 15 cm, and height of 30 cm. Calculate the volume and total surface area.
Solution: Volume = (pi x 30 / 3) x (12^2 + 12 x 15 + 15^2)\n= (10pi) x (144 + 180 + 225)\n= 10pi x 549 = 5490pi = 17,247.8 cm^3 = 17.25 liters\nSlant height = sqrt(30^2 + (12-15)^2) = sqrt(900 + 9) = 30.15 cm\nLateral area = pi x (12 + 15) x 30.15 = 813.15pi = 2,554.5 cm^2\nTop area = pi x 15^2 = 225pi = 706.9 cm^2\nBottom area = pi x 12^2 = 144pi = 452.4 cm^2\nTotal = 3,713.7 cm^2
Result: Volume: 17,247.8 cm^3 (17.25 L) | Total Surface Area: 3,713.7 cm^2
Example 2: Concrete Footing Volume
Problem: A frustum-shaped concrete footing has a 4 ft bottom radius, 2 ft top radius, and 3 ft height. Calculate cubic yards of concrete needed.
Solution: Volume = (pi x 3 / 3) x (4^2 + 4 x 2 + 2^2)\n= pi x (16 + 8 + 4)\n= 28pi = 87.96 ft^3\nConvert to cubic yards: 87.96 / 27 = 3.26 cubic yards\nSlant height = sqrt(3^2 + (4-2)^2) = sqrt(9 + 4) = 3.61 ft\nLateral area = pi x (4 + 2) x 3.61 = 21.66pi = 68.04 ft^2
Result: Volume: 87.96 ft^3 (3.26 cubic yards) | Lateral Area: 68.04 ft^2
Frequently Asked Questions
What is a frustum and how is it formed?
A frustum is a three-dimensional geometric solid created by cutting a cone or pyramid with a plane parallel to its base. This cut removes the top portion (the apex region) and leaves a shape with two parallel faces of different sizes connected by a sloping lateral surface. The word frustum comes from the Latin word meaning 'morsel cut off.' Frustums appear frequently in everyday life: drinking cups, buckets, lampshades, and architectural columns are all examples of conical frustums. The frustum retains the symmetry properties of its parent shape, meaning a frustum of a right circular cone has a circular cross-section at every height.
How is the volume of a frustum calculated?
The volume of a frustum of a cone is calculated using the formula V = (pi times h divided by 3) times (R squared plus R times r plus r squared), where h is the height, R is the radius of the larger base, and r is the radius of the smaller base. This formula can be derived by subtracting the volume of the removed small cone from the volume of the original full cone. For a frustum of a square pyramid, the formula is V = (h/3)(A1 + A2 + sqrt(A1 times A2)), where A1 and A2 are the areas of the two parallel faces. Both formulas reduce to the full cone or pyramid volume formula when the top radius or area equals zero.
What is the slant height of a frustum and how is it found?
The slant height of a frustum is the shortest distance measured along the lateral (sloping) surface from the edge of one base to the corresponding edge of the other base. For a conical frustum, the slant height is calculated using the Pythagorean theorem: slant height equals the square root of (h squared plus (R minus r) squared), where h is the perpendicular height and R and r are the bottom and top radii. This relationship exists because if you unfold a vertical cross-section of the frustum, the height, the radius difference, and the slant height form a right triangle. The slant height is essential for calculating the lateral surface area of the frustum.
How is the lateral surface area of a frustum computed?
The lateral surface area of a conical frustum is the area of the curved surface that connects the two circular bases, excluding the top and bottom faces. The formula is Lateral Area = pi times (R plus r) times the slant height, where R is the larger radius, r is the smaller radius, and the slant height equals sqrt(h squared plus (R minus r) squared). This formula can be understood geometrically: if you unroll the lateral surface, it forms a flat shape called an annular sector, and pi times (R plus r) represents the average circumference of the two bases. The total surface area is found by adding the areas of both circular bases to the lateral area.
What are common real-world applications of frustum calculations?
Frustum calculations are used extensively in engineering, architecture, and manufacturing. In civil engineering, dam cross-sections, retaining walls, and foundation footings are often frustum-shaped, requiring volume calculations for material estimation. In manufacturing, tapered containers like buckets, cups, and funnels require frustum geometry for determining material usage and capacity. Architectural features like tapered columns, cooling towers, and spires use frustum mathematics for structural design. In agriculture, grain storage bins and water tanks are frequently frustum-shaped. Even in optics and lighting, the beam spread of a flashlight or projector creates a frustum shape, and calculating illumination requires understanding frustum geometry.
How does a frustum relate to its parent cone or pyramid?
A frustum can always be related back to its parent cone or pyramid through geometric similarity. If the frustum has bottom radius R, top radius r, and height h, the full height of the original cone would be H = hR/(R-r), derived from similar triangles. The removed apex portion has height H-h = hr/(R-r). The volume of the frustum equals the volume of the full cone minus the volume of the removed cap. This relationship is useful for deriving frustum formulas and for understanding proportionality. For example, a frustum created by cutting a cone at half its height retains 7/8 of the original volume, not 1/2 as many people intuitively guess, because volume scales with the cube of linear dimensions.