Calculate cone height from slant height, volume, lateral area, total surface area, or diameter. Shows all cone properties including volume, surface area, and half-angle with visual breakdowns.
The height of a right circular cone is the perpendicular distance from the center of its circular base to its apex. It is one of the three fundamental linear measurements of a cone — along with the base radius and the slant height — and determines the cone's volume, surface area, and overall proportions. In many practical problems, you know a different measurement and need to solve for the height.
This calculator supports five input modes: slant height and radius, volume and radius, lateral surface area and radius, total surface area and radius, or diameter and slant height. For each mode, it algebraically isolates the height and then computes every remaining property — volume, base area, lateral surface area, total surface area, slant height, diameter, and the half-angle (the angle between the cone's axis and its slant surface).
Visual bars compare all linear dimensions and show how the total surface area splits between the base and the lateral surface. A complete properties table lists every value with its formula, and a reference table covers key cone relationships — the Pythagorean connection between h, r, and l, volume comparison with a cylinder, sector angle of the unrolled surface, and the centroid location. Eight presets let you jump straight to common examples. Whether you are working through geometry homework, designing conical containers, or engineering funnel-shaped parts, this tool delivers accurate results with full transparency into the underlying math.
This calculator is especially useful when you know one cone measurement indirectly and need to recover the vertical height without manually rearranging several formulas. In classwork, that often means starting from slant height or volume; in design work, it can mean backing into the height from available material area or a measured diameter.
Because the tool also returns radius, slant height, volume, surface areas, and half-angle together, it is helpful for comparing shape proportions instead of solving a single number in isolation. That makes it practical for geometry homework, container design, funnels, hoppers, and any conical part where both capacity and surface coverage matter.
h = √(l² − r²) from slant height. h = 3V / (πr²) from volume. l = Lateral Area / (πr), then h = √(l² − r²). Total SA = πr² + πrl, solve for l then h. Volume = ⅓πr²h. Lateral SA = πrl. Half-angle = arctan(r/h).
Result: Height = 12 cm
With mode set to slant-radius, enter inputA = 13 and inputB = 5. The calculator uses h = √(l² − r²) = √(13² − 5²) = 12 cm. It then fills in the remaining cone properties, including volume ≈ 314.16 cm³, lateral surface area ≈ 204.20 cm², total surface area ≈ 282.74 cm², and half-angle ≈ 22.62°.
A right circular cone ties together height, radius, and slant height through the Pythagorean relationship $l^2 = h^2 + r^2$. That makes slant height the most direct way to recover the vertical height, but it is not the only option. If you know the volume and radius, the calculator rearranges $V = rac{1}{3}pi r^2 h$ to isolate $h$. If you know lateral area or total surface area, it first recovers the slant height and then solves for the perpendicular height.
This is useful because real problems rarely hand you the exact measurement you want. A drawing might list diameter and slant height, while a manufacturing spec might list total exposed area. The calculator handles those reverse-solve cases in one place so you do not have to redo the algebra every time.
Height alone does not tell you whether a cone is narrow, steep, wide, or shallow. That is why the calculator also reports slant height, diameter, base area, lateral area, total surface area, and the half-angle. The half-angle is especially helpful when comparing pointed cones to broad cones because it translates the geometry into a single angle measured from the axis to the surface.
The dimension bars and surface-area breakdown also make it easier to interpret the result. A cone with a modest height but very large radius may still require substantial material because the lateral surface grows with both radius and slant height. Looking at the derived values together gives a better engineering picture than height alone.
Cone height calculations appear in geometry coursework, but they are also common in funnels, hoppers, nozzles, roofing features, packaging, and conical tanks. In those settings, the vertical height affects storage capacity, clearance, and how steeply material flows through the shape.
When checking a physical object, keep all measurements in the same unit system before entering them. If your slant height is very close to the radius, the cone is extremely shallow, so small measurement errors can noticeably change the computed height. For accurate work, measure carefully and round only after the calculator has finished all intermediate steps.
Height (h) is the perpendicular distance from base center to apex. Slant height (l) is the distance along the surface from the base edge to the apex. They are related by l² = h² + r².
Rearrange V = ⅓πr²h to get h = 3V / (πr²). Enter the volume and radius in this calculator.
The half-angle is the angle between the cone's central axis and the slant surface, calculated as arctan(r / h). Understanding this concept helps you apply the calculator correctly and interpret the results with confidence.
No — this calculator is for right circular cones only, where the apex is directly above the center of the base. Use this as a practical reminder before finalizing the result.
That is impossible. Total SA always equals base area plus lateral area, so it must exceed πr².
Both are pointed solids with ⅓ the volume of their prismatic counterpart. A cone has a circular base; a pyramid has a polygonal base.