spiral
Our editors will review what you’ve submitted and determine whether to revise the article.
- Related Topics:
- curve
- Fermat’s spiral
- logarithmic spiral
- Spiral of Archimedes
spiral, plane curve that, in general, winds around a point while moving ever farther from the point. Many kinds of spirals are known, the first dating from the days of ancient Greece. The curves are observed in nature, and human beings have used them in machines and in ornament, notably architectural—for example, the whorl in an Ionic capital. The two most famous spirals are described below.
Although the Greek mathematician Archimedes did not discover the spiral that bears his name, he did employ it in his On Spirals (c. 225 bce) to square the circle and trisect an angle. The equation of the spiral of Archimedes is r = aθ, in which a is a constant, r is the length of the radius from the centre, or beginning, of the spiral, and θ is the angular position (amount of rotation) of the radius. Like the grooves in a phonograph record, the distance between successive turns of the spiral is a constant—2πa, if θ is measured in radians.
The logarithmic, or equiangular, spiral was discovered by the French scientist René Descartes in 1638. In 1692 the Swiss mathematician Jakob Bernoulli named it spira mirabilis (“miracle spiral”) for its mathematical properties; it is carved on his tomb. The general equation of the logarithmic spiral is r = aeθ cot b, in which r is the radius of each turn of the spiral, a and b are constants that depend on the particular spiral, θ is the angle of rotation as the curve spirals, and e is the base of the natural logarithm. Whereas successive turns of the spiral of Archimedes are equally spaced, the distance between successive turns of the logarithmic spiral increases in a geometric progression (such as 1, 2, 4, 8,…). Among its other interesting properties, every ray from its centre intersects every turn of the spiral at a constant angle (equiangular), represented in the equation by b. Also, for b = π/2 the radius reduces to the constant a—in other words, to a circle of radius a. This approximate curve is observed in spiderwebs and to a greater degree of accuracy in the chambered nautilus and in certain flowers.