The Cavalieri’s Principle

A fundamental theorem in Euclidean geometry states that the sum of the measures of the three interior angles of any triangle is always equal to two right angles, or 180 degrees. This property, [latex]\alpha + \beta + \gamma = 180^\circ[/latex], is a direct consequence of the parallel postulate and holds true for all triangles, regardless of their size or shape, within a flat, Euclidean plane.

The Platonic solids are the only five convex regular polyhedra: a regular polyhedron has congruent regular polygonal faces and the same number of faces meeting at each vertex. The five solids are the tetrahedron (4 faces), cube (6 faces), octahedron (8 faces), dodecahedron (12 faces), and icosahedron (20 faces). Their symmetry and properties have been studied since antiquity.

This is a historically notable problem in mathematics. Its negative resolution by Leonhard Euler in 1736 laid the foundations of graph theory and prefigured the idea of topology. The problem asked if the seven bridges of the city of Königsberg could all be traversed in a single trip without doubling back, with the trip ending on the same landmass it began.

A fundamental theorem in topology and geometry stating that for any convex polyhedron, the number of vertices (V), edges (E), and faces (F) are related by the formula [latex]V - E + F = 2[/latex]. This value, 2, is the Euler characteristic of a sphere, revealing a deep topological property independent of the polyhedron's specific shape.

A second-order linear elliptic partial differential equation that describes systems in a steady-state or equilibrium condition. It is written as [latex]nabla^2 u = 0[/latex] or [latex]Delta u = 0[/latex], where [latex]nabla^2[/latex] (or [latex]Delta[/latex]) is the Laplace operator. Solutions, called harmonic functions, are the smoothest possible functions and represent potentials in fields like electrostatics, gravitation, and fluid flow.

Theorema Egregium (Latin for "Remarkable Theorem") states that the Gaussian curvature of a surface is an intrinsic property. This means it depends only on how distances are measured on the surface itself, not on how the surface is embedded in three-dimensional space. A flat sheet of paper can be rolled into a cylinder but not a sphere without stretching.

Euclid's five postulates form the axiomatic basis for Euclidean geometry as described in his treatise, 'Elements'. They are fundamental assumptions from which all other theorems are logically derived. The first four concern the construction of lines and circles, while the fifth, the parallel postulate, uniquely defines the flat, non-curved nature of Euclidean space. These axioms established the deductive method in mathematics.

Euclid's fifth postulate, the parallel postulate, is the axiom that defines Euclidean geometry: it states that if a line intersects two other lines, and the interior angles on one side sum to less than two right angles ([latex]\alpha + \beta < 180^\circ[/latex]), then the two lines will eventually intersect on that side. This postulate guarantees a unique parallel line through a point not on a given line.

The Pythagorean theorem is a fundamental relation in Euclidean geometry among the three sides of a right-angled triangle. It states that the area of the square whose side is the hypotenuse (the side opposite the right angle) is equal to the sum of the areas of the squares on the other two sides. The formula is expressed as [latex]a^2 + b^2 = c^2[/latex].

The Cartesian coordinate system provides an algebraic model for Euclidean geometry. It uses one or more numbers, or coordinates, to uniquely determine the position of a point in space. In a plane, two perpendicular lines (the x-axis and y-axis) are used, allowing geometric shapes to be described by algebraic equations. This fusion of algebra and geometry is known as analytic geometry.

A second-order linear hyperbolic partial differential equation that governs the propagation of various types of waves. In its simplest form, it is written as [latex]\frac{\partial^2 u}{\partial t^2} = c^2 \nabla^2 u[/latex], where [latex]u(\vec{x},t)[/latex] is the amplitude of the wave, [latex]c[/latex] is the wave speed, and [latex]\nabla^2[/latex] is the Laplace operator. It models phenomena like vibrating strings, sound waves, and light waves.

The Euler characteristic is a topological invariant, a number that describes a topological space's structure or shape regardless of how it is bent. For polyhedra, it is defined by the formula [latex]\chi = V - E + F[/latex], where V, E, and F are the number of vertices, edges, and faces, respectively. For a sphere, [latex]\chi = 2[/latex], while for a torus, [latex]\chi = 0[/latex].

A fundamental second-order linear parabolic partial differential equation describing heat distribution or other diffusion processes. Its canonical form is [latex]\frac{partial u}{partial t} = \alpha \nabla^2 u[/latex], where [latex]u(\vec{x},t)[/latex] is temperature, [latex]t[/latex] is time, and [latex]\alpha[/latex] is thermal diffusivity. Solutions model how an initial temperature distribution evolves, smoothing out irregularities over time and approaching a steady state.

A fundamental solution of a linear partial differential operator [latex]L[/latex] is a solution to the equation [latex]Lu = delta(x)[/latex], where [latex]delta(x)[/latex] is the Dirac delta function. It represents the response of the system to a point source or impulse. Once known, the solution to the inhomogeneous equation [latex]Lu = f(x)[/latex] can be found by convolution: [latex]u(x) = (G * f)(x)[/latex], where [latex]G[/latex] is the fundamental solution.