The golden ratio or golden mean, represented by the Greek letter phi (ϕ), is an irrational number that approximately equals 1.618. The golden ratio results when the ratio of two numbers is the same as the ratio of their sum to the larger of the two numbers. In other words, the golden ratio occurs when you divide a line segment into two smaller segments of different lengths for which the ratio of the whole line segment to the longer segment is equal to the ratio of the longer segment to the shorter segment.\n\nThe golden ratio is a special number, and its story begins with the ancient greeks.\n\n1. __300 BC__: Greek mathematician Euclid provided the first written definition of the golden ratio in his math textbook *Elements*. At the time, Euclid called it the "extreme and mean ratio.”\n2. __1509 AD__: Italian mathematician Luca Paciolifurther used the golden proportion to describe the natural world in his book *De Divina Proportione* (*On the Divine Proportion*), which was illustrated by Leonardo da Vinci. \n3. __1835__: German mathematician Martin Ohm first described the ratio as “golden” when he used the term *goldener schnitt*, which translates to “golden section.” \n4. __1910__: American mathematician Mark Barr first used the Greek letter phi (ϕ) to represent the golden ratio.\n\nThe golden ratio occurs when you take a line segment and divide it into two smaller segments of different lengths where the ratio of the whole line segment to the longer segment is equal to the ratio of the longer segment to the shorter segment. Two quantities a and b have a golden ratio relationship if\nwhere a \u003e b \u003e 0 and the Greek letter phi (ϕ) represents the golden ratio. The golden ratio expressed numerically is \n\nSince the number phi is irrational, the digits after the decimal point continue on forever without repeating.\n\nThe golden ratio is closely connected to the [Fibonacci sequence](https://www.masterclass.com/articles/fibonacci-sequence-formula). This is because as the Fibonacci numbers increase, the ratio of any two consecutive Fibonacci numbers gets closer and closer to the golden ratio. \n\nThe below examples of the golden ratio are exceptions rather than rules—in general, claims that the golden ratio appears throughout art, architecture, nature, and the human body are overstated. However, the golden ratio does feature prominently in a few natural and manmade examples.\n\n- __In plants__: You can find the golden ratio in the spiral arrangement of leaves (called a phyllotaxis) on some plants, or in the golden spiral pattern of pinecones, cauliflower, pineapples, and the arrangement of seeds in sunflowers. \n- __In art__: Within the last century, artists have been inspired by the aesthetics of the golden ratio and incorporated it into their works. For example, the canvas of surrealist painter Salvador Dali's *The Sacrament of the Last Supper* is a golden rectangle, and the painting itself features a giant dodecahedron with edges in the golden ratio.\n- __In architecture__: The Parthenon in Greece incorporates the golden ratio in many of its design elements. In the twentieth century, Swiss architect Le Corbusier used the golden ratio in his Modulor system for the scale of architectural proportion. The United Nations Secretariat Building in New York City was designed using the golden ratio: the size and shape of the windows, columns, and some sections of the building are based on the golden ratio. \nGet the [MasterClass Annual Membership](https://www.masterclass.com) for exclusive access to video lessons taught by business and science luminaries, including Neil deGrasse Tyson, Chris Hadfield, Jane Goodall, and more.\nThe golden ratio is a famous mathematical concept that is closely tied to the Fibonacci sequence.