Calculate all properties of a regular octagon from side length, area, perimeter, apothem, or circumradius. Includes area, perimeter, apothem, three types of diagonals, circumradius, and angles.
The regular octagon — an eight-sided polygon with all sides and angles equal — is perhaps most recognizable as the shape of stop signs worldwide. Its 135° interior angles and near-circular profile make it a practical compromise between the structural simplicity of a square and the efficiency of a circle.
The area of a regular octagon is A = 2(1+√2)s² ≈ 4.828s², where s is the side length. This remarkably clean formula arises because a regular octagon can be constructed by cutting equal isosceles right triangles from the four corners of a square. The resulting shape has 20 diagonals in three distinct lengths: short diagonals connecting vertices two apart (s(1+√2)), medium diagonals connecting vertices three apart, and long diagonals connecting opposite vertices (equal to 2× the circumradius).
Octagons appear in architecture (the Florence Baptistery, the Tower of the Winds in Athens), sports (the UFC fighting ring is officially called "The Octagon" with sides of 3.66 m), everyday objects (umbrella frames, many clock faces), and of course traffic regulation — the octagonal stop sign was adopted internationally because its unique shape is recognizable even from behind or when covered in snow.
This calculator works in reverse too — enter the area, perimeter, apothem, or circumradius, and it derives the side length and every other property. Presets for real-world octagons let you explore instantly. The area efficiency section shows how close the octagon is to its circumscribed circle and bounding square.
Regular Octagon — Area, Perimeter, Diagonals & Properties problems often require several dependent steps, and a small arithmetic slip can propagate through every derived value. This calculator is tailored to that workflow: you enter solve from, unit, and it returns side length, area, perimeter, apothem (inradius) in one consistent pass. It is useful for homework checks, worksheet generation, tutoring walkthroughs, and fast field/design estimates where you need reliable geometry results without rebuilding the full derivation each time.
Area: A = 2(1+√2)s² ≈ 4.828s² Perimeter: P = 8s Apothem (inradius): a = s/(2 tan(π/8)) Circumradius: R = s/(2 sin(π/8)) Short diagonal: s(1+√2) Long diagonal: 2R Interior angle: 135° Central angle: 45° Number of diagonals: 20
Result: Area ≈ 482.84 cm², Perimeter = 80 cm, Circumradius ≈ 13.07 cm
For a regular octagon with side 10 cm: Area = 2(1+√2) × 100 ≈ 482.84 cm². Perimeter = 8 × 10 = 80 cm. Apothem ≈ 12.07 cm. Circumradius ≈ 13.07 cm. Short diagonal ≈ 24.14 cm. Long diagonal ≈ 26.13 cm. The octagon fills about 90% of its circumscribed circle.
This regular octagon — area, perimeter, diagonals & properties tool links the entered values (solve from, unit) to the target geometry relationships used in class and practice problems. Instead of solving each intermediate step manually, you can validate setup and arithmetic quickly while still tracing which measurements drive the final result.
Formula focus: the calculator formula
Regular Octagon — Area, Perimeter, Diagonals & Properties shows up in school geometry, technical drafting, construction layout checks, and early engineering design estimates. When values are changed repeatedly, the calculator helps you compare scenarios quickly and see how sensitive the shape is to each dimension.
Start with the primary outputs (side length, area, perimeter, apothem (inradius)) and then use the remaining cards/tables to confirm consistency with your diagram. Keep units consistent across inputs, and round only at the end if your assignment or project specifies a fixed precision.
A = 2(1+√2)s², where s is the side length. This equals approximately 4.828s². For side 10: A = 2(1+1.414) × 100 ≈ 482.84 square units.
20 diagonals, from the formula n(n−3)/2 = 8(8−3)/2 = 20. They come in three distinct lengths: short (vertices 2 apart), medium (vertices 3 apart), and long (opposite vertices).
The octagon was chosen in 1923 because an eight-sided shape is unique among common road signs, making it identifiable even from behind (where text isn't visible) or when covered with snow. The red color was standardized later in 1954.
135°. From (n−2)×180°/n = (8−2)×180°/8 = 1080°/8 = 135°. The sum of all interior angles is 1080°.
Cut equal isosceles right triangles from all four corners of a square. If the square has side L, the octagon side length is s = L / (1 + √2). This construction is used in woodworking, tiling, and origami.
Regular octagons alone cannot tile a plane (135° doesn't divide 360° evenly). However, octagons paired with squares form the classic "truncated square tiling" — one of the 11 Archimedean tilings. This pattern is common in floor tiles and Islamic art.