Calculate the area, perimeter, arc length, centroid, and moment of inertia of a quarter circle (quadrant). Enter radius or diameter for instant results.
A quarter circle — also called a quadrant — is one-fourth of a full circle, formed by two perpendicular radii and the arc between them. It appears constantly in mathematics, engineering, and design: from the rounded corners of a smartphone screen to the cross-sections of structural beams and the quadrant of a unit circle in trigonometry. This Quarter Circle Calculator lets you enter a radius (or diameter) and instantly computes every important geometric property: area (πr²/4), total perimeter (arc + two straight radii), arc length (πr/2), the centroid location (4r/3π from the center along each axis), and the second moment of area (moment of inertia) used in structural analysis. Visual comparison bars show how a quarter circle relates to the full circle in area, perimeter, and arc, while a perimeter breakdown bar reveals the proportion of curved versus straight edges. Eight preset radii and a full reference table covering radii from 1 to 100 let you explore values quickly. Choose from six measurement units and up to 10 decimal places for precise engineering or academic calculations. Whether you are a geometry student, structural engineer, or designer working with rounded shapes, this tool gives you complete quarter-circle analysis in one place.
A quarter circle shows up whenever a design uses a rounded corner, a 90-degree bend, or a quadrant-based cross section. This calculator brings the most useful values together in one place, so you do not have to jump between separate area, arc, centroid, and inertia formulas while checking a sketch or solving an assignment.
It is especially useful because quarter-circle problems often mix geometric and engineering questions. A student may care about area and perimeter, while a structural or mechanical workflow may care about centroid position and second moment of area. This tool covers both without changing the underlying input.
Area = πr² / 4 Arc Length = πr / 2 Perimeter = πr/2 + 2r Centroid (from corner) = 4r / (3π) Moment of Inertia Ix = Iy = πr⁴ / 16 Polar Moment J = πr⁴ / 8
Result: Area = 78.5398 cm², perimeter = 35.7080 cm, arc length = 15.7080 cm, centroid = 4.2441 cm.
With inputMode set to radius and radius = 10 cm, the calculator uses the standard quadrant formulas. The area is πr²/4 = 78.5398 cm², the arc length is πr/2 = 15.7080 cm, and the full perimeter is the arc plus two radii, or 35.7080 cm. The centroid is 4r/(3π) = 4.2441 cm from each straight edge, which is why quarter circles are common examples in centroid and section-property problems.
A quarter circle is defined by the same radius as its parent circle, so nearly every result begins with r. The area is πr²/4, the arc length is πr/2, and the total perimeter is πr/2 + 2r because the curved edge is paired with two straight radii. That combination is what makes quadrant problems slightly different from simply taking one-fourth of every full-circle measurement.
This calculator keeps those relationships together so you can move from a single radius or diameter input to the full set of useful outputs without rewriting each formula by hand.', + '
Quarter circles are not just classroom shapes. They appear in plate corners, concrete fillets, gusset details, duct transitions, and rounded architectural cutouts. In those contexts, the centroid location tells you where the area is effectively balanced, and the moment of inertia tells you how resistant that shape is to bending about an axis.
Because a quarter circle packs area close to the corner, its centroid sits at 4r/(3π) from each straight side. That makes it a standard example in mechanics-of-materials courses and a common reference in section-property tables.', + '
If you already know the radius, use it directly because every formula is simplest in terms of r. If you measured across the full width of the original circle, the diameter mode is faster and avoids a manual conversion step. Both modes produce the same outputs, but the best choice depends on how the dimension is given in your drawing, worksheet, or part specification.
That small convenience matters when you are checking several rounded features in a row. Using the same measurement language as the source drawing reduces mistakes and makes the calculator easier to use in real workflows.
A quarter circle (quadrant) is exactly one-fourth of a full circle. It is bounded by two radii at 90° and the arc connecting their endpoints.
Divide the full circle area by 4: A = πr²/4, where r is the radius. Use this as a practical reminder before finalizing the result.
The perimeter consists of the arc (πr/2) plus two straight radii (2r), giving P = πr/2 + 2r ≈ 3.5708r.
For a quarter circle in the first quadrant with the right-angle at the origin, the centroid is at (4r/3π, 4r/3π) — about 0.4244r from the corner along each axis.
About either centroidal axis through the bounding radii: Ix = Iy = πr⁴/16. The polar moment is J = πr⁴/8.
A quarter circle is a specific sector with a central angle of exactly 90°. A sector can have any central angle from 0° to 360°.