{ "cells": [ { "cell_type": "markdown", "id": "2c9e7ca0", "metadata": {}, "source": [ "**Euler's formula** states that for any real number $\\theta$,\n", "\n", "$$\\label{eq:1}\n", "e^{i \\theta} = \\cos\\theta + i \\sin\\theta, \\tag{1}\n", "$$\n", "\n", "where $i$ is the imaginary unit, defined as $i^2 = -1$. The formula has a geometric interpretation in the complex plane that provides insight into trigonometry and complex numbers, **Figure 1**.\n", "\n", "In **Figure 1**, the horizontal axis represents the real part, the vertical axis represents the imaginary part, and any complex number $z = x + i y$ is plotted as the point $(x, y)$. Euler's formula represents a point on the unit circle at angle $\\theta$ from the positive real axis, where:\n", "\n", "- **Real part**: $\\cos\\theta$ (horizontal coordinate)\n", "- **Imaginary part**: $\\sin\\theta$ (vertical coordinate)\n", "- **Magnitude**: $|e^{i\\theta}| = \\sqrt{\\cos^2\\theta + \\sin^2\\theta} = 1$\n", "\n", "As $\\theta$ varies from $0$ to $2\\pi$, the point $e^{i\\theta}$ traces out the entire unit circle. The famous **Euler's identity** emerges naturally:\n", "\n", "$$\n", "e^{i \\pi} = \\cos(\\pi) + i \\sin(\\pi) = -1 + 0 i = -1,\n", "$$\n", "\n", "or\n", "\n", "$$\n", "e^{i \\pi} + 1 = 0.\n", "$$\n", "\n", "Now, let's go back to $\\eqref{eq:1}$. We know that $\\cos(x)$ is an even function, meaning $\\cos(-x) = \\cos(x)$, and $\\sin(x)$ is an odd function, meaning $\\sin(-x) = -\\sin(x)$. Using that, we can derive the following identity:\n", "\n", "$$\\label{eq:2}\n", "e^{-i \\theta} = e^{i (-\\theta)} = \\cos(-\\theta) + i \\sin(-\\theta) = \\cos\\theta - i \\sin\\theta. \\tag{2}\n", "$$" ] }, { "cell_type": "markdown", "id": "56fc4761", "metadata": {}, "source": [] } ], "metadata": { "kernelspec": { "display_name": "blog", "language": "python", "name": "python3" }, "language_info": { "name": "python", "version": "3.11.9" } }, "nbformat": 4, "nbformat_minor": 5 }