Calculate the slant height of a cone from radius and height, lateral surface area, or total surface area. View all cone properties including volume, surface areas, and apex angle.
The slant height of a cone is the distance measured along the lateral surface from the base edge to the apex. It is one of the most important measurements in cone geometry because it directly determines the lateral surface area—the amount of material needed to construct the cone's curved surface. This calculator supports three input modes to accommodate different problem types. In the most common mode you enter the radius and the perpendicular height, and the slant height is found via the Pythagorean theorem: l = √(r² + h²). Alternatively, if you know the lateral surface area and the radius, the slant height can be back-calculated as l = Lateral SA / (π · r). A third mode derives the slant height from the total surface area and the radius. Beyond the slant height itself, the calculator displays the full set of cone properties: volume (⅓πr²h), lateral surface area (πrl), total surface area (πr(r + l)), and the half-apex angle. Eight presets showcase cones encountered in textbooks, engineering, and everyday objects, while a reference table collects all key formulas in one place. Visual proportion bars let you compare dimensions at a glance.
This cone calculator is useful when you need to move between different types of known information. In some problems you are given radius and perpendicular height, but in manufacturing or worksheet problems you may instead be given a surface area and asked to recover the geometry. Switching between those starting points without losing track of the cone relationships is where mistakes usually happen, and this tool keeps those conversions consistent.
Slant height l = √(r² + h²). Lateral SA = π · r · l. Total SA = π · r · (r + l). Volume = ⅓ · π · r² · h. Half-apex angle θ = arctan(r / h).
Result: Slant height ≈ 5.00, height ≈ 4.00, lateral SA ≈ 47.13, volume ≈ 37.71
Using total surface area mode with radius 3 and total surface area 75.4, the calculator first subtracts the base area πr² ≈ 28.27 to isolate the lateral area. Dividing the remaining area by πr gives l ≈ 5.00. With radius 3 and slant height 5, the perpendicular height is √(5² − 3²) = 4, so the cone is the familiar 3-4-5 case.
A right circular cone becomes much easier to understand when you slice it through the axis. That cross section forms an isosceles triangle, and one half of it is a right triangle with legs r and h and hypotenuse l. The standard slant-height formula is therefore just the Pythagorean theorem in disguise. Once that picture is clear, many other cone formulas feel less like memorization and more like direct consequences of the geometry.
Many exercises and practical problems do not give the height directly. Instead, you may know the curved surface area from a material sheet or the total outside area from a finished object. In those cases, solving for slant height first is the cleanest route. After that, the height can be recovered from l² = r² + h². This calculator handles that reversal automatically, which is especially helpful when small rounding differences would otherwise propagate through several manual steps.
The half-apex angle describes how narrow or wide the cone opens, the lateral area tells you how much curved material is required, and the total surface area adds the circular base. Looking at those values together is useful in applications like funnels, roofs, hoppers, packaging, and pattern cutting. Two cones can share the same slant height but have very different radii and opening angles, so the surrounding measurements provide context that a single dimension alone cannot capture.
The slant height is the straight-line distance from a point on the edge of the circular base to the apex of the cone, measured along the surface. Use this as a practical reminder before finalizing the result.
In a right circular cone, the radius, height, and slant height form a right triangle. Therefore l = √(r² + h²).
Yes. From lateral SA: l = Lateral SA / (π · r). From total SA: l = (Total SA / (π · r)) − r.
The full apex angle is twice the angle between the slant height and the axis. The half-apex angle θ = arctan(r / h).
This calculator is designed for right circular cones where the apex is directly above the centre of the base. Keep this note short and outcome-focused for reuse.
It determines how much material is needed for the lateral surface—essential for manufacturing funnels, party hats, ice-cream cones, and roof structures. Apply this check where your workflow is most sensitive.