Euler's identity

Euler's identity, or Euler's equation, named after Leonhard Euler, is the equation of mathematical analysis ${\displaystyle e^{i\pi }+1=0.\,\!}$

Quotes

• One of the most frequently mentioned equations was Euler's equation, ${\displaystyle e^{i\pi }+1=0.\,\!}$ Respondents called it "the most profound mathematical statement ever written"; "uncanny and sublime"; "filled with cosmic beauty"; and "mind-blowing". Another asked: "What could be more mystical than an imaginary number interacting with real numbers to produce nothing?" The equation contains nine basic concepts of mathematics — once and only once — in a single expression. These are: e (the base of natural logarithms); the exponent operation; π; plus (or minus, depending on how you write it); multiplication; imaginary numbers; equals; one; and zero.
  • Robert P. Crease, in "The greatest equations ever" at PhysicsWeb (October 2004)

• 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.
  • Keith Devlin, “The Most Beautiful Equation,” Wabash Magazine, Winter/Spring 2002. As quoted in Dr. Euler's Fabulous Formula : Cures Many Mathematical Ills (2006) ISBN 978-0691118222

• There is a famous formula, perhaps the most compact and famous of all formulas — developed by Euler from a discovery of de Moivre: ${\displaystyle e^{i\pi }+1=0.\,\!}$ It appeals equally to the mystic, the scientist, the philosopher, the mathematician.
  • Edward Kasner and James R. Newman, in Mathematics and the Imagination (1940)

• Gentlemen, that is surely true, 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.
  • Benjamin Peirce, as quoted in notes by W. E. Byerly, published in Benjamin Peirce, 1809-1880 : Biographical Sketch and Bibliography (1925) by R. C. Archibald; also in Mathematics and the Imagination (1940) by Edward Kasner and James Newman

• For any real number x, Euler’s formula is

${\displaystyle e^{ix}=\cos x+i\sin x\,\!}$

Where e is fundamental constant (the base of natural logarithms) and i = √-1. If we now put x =π, we get e^(iπ) = cos π+i sin π, and since cos(π) =−1 and sin(π) = 0, this reduces to e^(iπ) =−1 so that e^(iπ) +1=0.

• David Darling, in The Universal Book of Mathematics: From Abracadabra to Zeno's Paradoxes (2004), John Wiley & Sons, p. 111

• This most extraordinary equation first emerged in Leonard Euler’s Introductio in 1748.
  • David Darling, in The Universal Book of Mathematics : From Abracadabra to Zeno's Paradoxes (2004), p. 111

• Since high school I have been utterly fascinated by the “mystery” of ${\displaystyle i={\sqrt {-1}}}$ and by the beautiful calculations that flow, seemingly without end, from complex numbers and functions of complex variables.
  • Paul J. Nahin, in Dr. Euler's Fabulous Formula: Cures Many Mathematical Ills (2011), Princeton University Press, p. xiii

• -1 = e^iπ,
  proves that Euler was a sly guy.

But ζ(2)
was totally new

And raised respect for him sky-high.

• William C. Waterhouse, as quoted in Dr. Euler's Fabulous Formula : Cures Many Ills (2011), by Paul J. Nahin, p. xiii

External links

Wikipedia has an article about:

Euler's identity

Wikimedia Commons has media related to:

Euler's formula

Mathematics
Mathematicians (by country)	Abel • Anaxagoras • Archimedes • Aristarchus of Samos • Averroes • Arnold • Banach • Cantor • Cartan • Chern • Cohen • Descartes • Diophantus • Erdős • Euclid • Euler • Fourier • Gauss • Gödel • Grassmann • Grothendieck • Hamilton • Hilbert • Hypatia • Lagrange • Laplace • Leibniz • Milnor • Newton • von Neumann • Noether • Penrose • Perelman • Poincaré • Pólya • Pythagoras • Riemann • Russell • Schwartz • Serre • Tao • Tarski • Thales • Turing • Weil • Weyl • Wiles • Witten
Numbers	1 • 23 • 360 • e • π • Fibonacci numbers • Irrational number • Negative number • Number • Prime number • Quaternion • Octonion
Concepts	Abstraction • Algorithms • Axiomatic system • Completeness • Deductive reasoning • Differential equation • Dimension • Ellipse • Elliptic curve • Exponential growth • Infinity • Integration • Geodesic • Induction • Proof • Partial differential equation • Principle of least action • Prisoner's dilemma • Probability • Randomness • Theorem • Topological space • Wave equation
Results	Euler's identity • Fermat's Last Theorem
Pure math	Abstract algebra • Algebra • Analysis • Algebraic geometry (Sheaf theory) • Algebraic topology • Arithmetic • Calculus • Category theory • Combinatorics • Commutative algebra • Complex analysis • Differential calculus • Differential geometry • Differential topology • Ergodic theory • Foundations of mathematics • Functional analysis • Game theory • Geometry • Global analysis • Graph theory • Group theory • Harmonic analysis • Homological algebra • Invariant theory • Logic • Non-Euclidean geometry • Nonstandard analysis • Number theory • Numerical analysis • Operations research • Representation theory • Ring theory • Set theory • Sheaf theory • Statistics • Symplectic geometry • Topology
Applied math	Computational fluid dynamics • Econometrics • Fluid mechanics • Mathematical physics • Science
History of math	Ancient Greek mathematics • Euclid's Elements • History of algebra • History of calculus • History of logarithms • Indian mathematics • Principia Mathematica
Other	Mathematics and mysticism • Mathematics education • Mathematics, from the points of view of the Mathematician and of the Physicist • Philosophy of mathematics • Unification in science and mathematics