Kokotsakis polyhedron is a polyhedral surface in three-dimensional space consisting of any number sided of a polygon as its base, and quadrilaterals are its lateral faces with triangles between the consecutive quadrilateral; for -sided polygonal base of a polyhedron, there are quadrilaterals and triangles.^[1]

The polyhedron was discovered when Kokotsakis (1933) studied the meshes wherein the perimeter of a polygon is surrounded by other polygons, showing an infinitesimally flexible in the case of a quadrilateral base, which was later known as Kokotsakis mesh.^[2] More examples of this special case of a Kokotsakis polyhedron were discovered by other mathematicians.^[3] Here, a polyhedron is flexible if the shape can be continuously changed while preserving the faces unchanged. Each of its vertexes is said to be "developable", meaning the sum of its plane angle is , resulting in the polyhedral surface being an origami crease pattern, which satisfies the Kawasaki's theorem.^[4] The work was done by Izmestiev (2017) in which classifying the folding angle for a Kokotsakis polyhedron in the case of a quadrangular base.^[5]

Stachel (2010) conjectured that there exists no polynomial system of irreducible resultant about the flexibility of a Kokotsakis polyhedron, which was later Izmestiev (2017) disproved it by showing the Kokotsakis polyhedron is orthodiagonal anti-involutive, meaning the planar angles has conditions such as all quadrilaterals are spherically orthodiagonal (any intersecting two diagonals in a quadrilateral form a right angle) and elliptic (the sum and difference of the edges of a quadrilateral are not equal to ), and the involution at common vertices are opposite.^[6]

As mentioned above, the Kokotsakis mesh was studied by Kokotsakis (1933), showing an infinitesimally flexible polyhedron in the case of a quadrilateral base.^[2] In general, the Kokotsakis mesh is defined as the infinite tessellations consisting of quadrilateral with congruent convex that is not trapezoidal and parallelogram.^[7] In the case of a quadrangle mesh, it is planar symmetric (exchanging adjacent vertices in-between), translation (two adjacent vertices are translated, mapping the faces), isogonal (opposite angles at every vertex is equal or complementary), orthogonal (the faces are parallel to the planes), and line-symmetric (appearance is symmetrical by half-rotating between two adjacent vertices around an axis passing through).^[8]

The Kokotsakis mesh can be used to construct cylindrical polyhedra.^[9]

• Bricard octahedron, a member of flexible polyhedra.