Euler's identity

Euler's identity is often cited as an example of deep mathematical beauty. Three of the basic arithmetic operations occur exactly once each: addition, multiplication, and exponentiation. The identity also links five fundamental mathematical constants: • The number, the additive identity • The number, the multiplicative identity • The number (), the fundamental circle constant • The number (), also known as Euler's number, which occurs widely in mathematical analysis • The number, the imaginary unit such that The equation is often given in the form of an expression set equal to zero, which is common practice in several areas of mathematics. Stanford University mathematics professor Keith Devlin has said, "like a Shakespearean sonnet that captures the very essence of love, or a painting that brings out the beauty of the human form that is far more than just skin deep, Euler's equation reaches down into the very depths of existence". Paul Nahin, a professor emeritus at the University of New Hampshire who wrote a book dedicated to Euler's formula and its applications in Fourier analysis, said Euler's identity is "of exquisite beauty". Mathematics writer Constance Reid has said that Euler's identity is "the most famous formula in all mathematics". Benjamin Peirce, a 19th-century American philosopher, mathematician, and professor at Harvard University, after proving Euler's identity during a lecture, said that it "is absolutely paradoxical; we cannot understand it, and we don't know what it means, but we have proved it, and therefore we know it must be the truth". A 1990 poll of readers by The Mathematical Intelligencer named Euler's identity the "most beautiful theorem in mathematics". In a 2004 poll of readers by Physics World, Euler's identity tied with Maxwell's equations (of electromagnetism) as the "greatest equation ever". At least three books in popular mathematics have been published about Euler's identity: • ''Dr. Euler's Fabulous Formula: Cures Many Mathematical Ills'', by Paul Nahin (2011) • ''A Most Elegant Equation: Euler's formula and the beauty of mathematics'', by David Stipp (2017) • ''Euler's Pioneering Equation: The most beautiful theorem in mathematics'', by Robin Wilson (2018) ==Explanations==

Imaginary exponents , with the final point being the actual value of . It can be seen that as gets larger approaches a limit of −1. Euler's identity asserts that e^{i\pi} is equal to −1. The expression e^{i\pi} is a special case of the expression e^z, where is any complex number. In general, e^z is defined for complex by extending one of the definitions of the exponential function from real exponents to complex exponents. For example, one common definition is: e^z = \lim_{n\to\infty} \left(1+\frac z n \right)^n. Euler's identity therefore states that the limit, as approaches infinity, of (1 + \tfrac {i\pi}{n})^n is equal to −1. This limit is illustrated in the animation to the right. Euler's identity is a special case of Euler's formula, which states that for any real number , e^{ix} = \cos x + i\sin x where the inputs of the trigonometric functions sine and cosine are given in radians. In particular, when , e^{i \pi} = \cos \pi + i\sin \pi. Since \cos \pi = -1 and \sin \pi = 0, it follows that e^{i \pi} = -1 + 0 i, which yields Euler's identity: e^{i \pi} +1 = 0. Geometric interpretation Any complex number z = x + iy can be represented by the point (x, y) on the complex plane. This point can also be represented in polar coordinates as where is the absolute value of (distance from the origin), and \theta is the argument of (angle counterclockwise from the positive x-axis). By the definitions of sine and cosine, this point has cartesian coordinates of implying that According to Euler's formula, this is equivalent to saying {{nowrap|z = r e^{i\theta}.}} Euler's identity says that {{nowrap|-1 = e^{i\pi}.}} Since e^{i\pi} is r e^{i\theta} for = 1 and this can be interpreted as a fact about the number −1 on the complex plane: its distance from the origin is 1, and its angle from the positive x-axis is \pi radians. Additionally, when any complex number is multiplied by {{nowrap|e^{i\theta},}} it has the effect of rotating z counterclockwise by an angle of \theta on the complex plane. Since multiplication by −1 reflects a point across the origin, Euler's identity can be interpreted as saying that rotating any point \pi radians around the origin has the same effect as reflecting the point across the origin. Similarly, setting \theta equal to 2\pi yields the related equation {{nowrap|e^{2\pi i} = 1,}} which can be interpreted as saying that rotating any point by one turn around the origin returns it to its original position. ==Generalizations==

Euler's identity is also a special case of the more general identity that the th roots of unity, for , add up to 0: \sum_{k=0}^{n-1} e^{2 \pi i \frac{k}{n}} = 0 . Euler's identity is the case where . A similar identity also applies to quaternion exponential: let be the basis quaternions; then, e^{\frac{1}{\sqrt 3}(i \pm j \pm k)\pi} + 1 = 0. More generally, let be a quaternion with a zero real part and a norm equal to 1; that is, q=ai+bj+ck, with a^2+b^2+c^2=1. Then one has e^{q\pi} + 1 = 0. The same formula applies to octonions, with a zero real part and a norm equal to 1. These formulas are a direct generalization of Euler's identity, since i and -i are the only complex numbers with a zero real part and a norm (absolute value) equal to 1. ==History==

Euler's identity is a direct result of Euler's formula, first published in his monumental 1748 work of mathematical analysis, Introductio in analysin infinitorum, but it is questionable whether the particular concept of linking five fundamental constants in a compact form can be attributed to Euler himself, as he may never have expressed it. Robin Wilson writes: == See also ==