Optic equation


In number theory, the optic equation is an equation that requires the sum of the reciprocals of two positive integers and to equal the reciprocal of a third positive integer :
Multiplying both sides by shows that the optic equation is equivalent to a Diophantine equation.

Solution

All solutions in integers are given in terms of positive integer parameters by
where are coprime.

Appearances in geometry

The optic equation, permitting but not requiring integer solutions, appears in several contexts in geometry.
In a bicentric quadrilateral, the inradius, the circumradius, and the distance between the incenter and the circumcenter are related by Fuss' theorem according to
and the distances of the incenter from the vertices are related to the inradius according to
In the crossed ladders problem, two ladders braced at the bottoms of vertical walls cross at the height and lean against the opposite walls at heights of and. We have Moreover, the formula continues to hold if the walls are slanted and all three measurements are made parallel to the walls.
Let be a point on the circumcircle of an equilateral triangle, on the minor arc. Let be the distance from to and be the distance from to. On a line passing through and the far vertex, let be the distance from to the triangle side. Then
In a trapezoid, draw a segment parallel to the two parallel sides, passing through the intersection of the diagonals and having endpoints on the non-parallel sides. Then if we denote the lengths of the parallel sides as and and half the length of the segment through the diagonal intersection as, the sum of the reciprocals of and equals the reciprocal of.
The special case in which the integers whose reciprocals are taken must be square numbers appears in two ways in the context of right triangles. First, the sum of the reciprocals of the squares of the altitudes from the legs equals the reciprocal of the square of the altitude from the hypotenuse. This holds whether or not the numbers are integers; there is a formula that generates all integer cases. Second, also in a right triangle the sum of the squared reciprocal of the side of one of the two inscribed squares and the squared reciprocal of the hypotenuse equals the squared reciprocal of the side of the other inscribed square.
The sides of a heptagonal triangle, which shares its vertices with a regular heptagon, satisfy the optic equation.

Other appearances

Thin lens equation

For a lens of negligible thickness, and focal length, the distances from the lens to an object,, and from the lens to its image,, are related by the thin lens formula:

Electrical engineering

Components of an electrical circuit or electronic circuit can be connected in what is called a series or parallel configuration. For example, the total resistance value of two resistors with resistances and connected in parallel follows the optic equation:
Similarly, the total inductance of two inductors with inductances connected in parallel is given by:
and the total capacitance of two capacitors with capacitances connected in series is as follows:

Paper folding

The optic equation of the crossed ladders problem can be applied to folding rectangular paper into three equal parts. One side is partially folded in half and pinched to leave a mark. The intersection of a line from this mark to an opposite corner, with a diagonal is exactly one third from the bottom edge. The top edge can then be folded down to meet the intersection.

Harmonic mean

The harmonic mean of and is or. In other words, is half the harmonic mean of and.

Relation to Fermat's Last Theorem

Fermat's Last Theorem states that the sum of two integers each raised to the same integer power cannot equal another integer raised to the power if. This implies that no solutions to the optic equation have all three integers equal to perfect powers with the same power. For if then multiplying through by would give which is impossible by Fermat's Last Theorem.