<?xml version="1.0" encoding="utf-8" standalone="yes"?><rss version="2.0" xmlns:atom="http://www.w3.org/2005/Atom"><channel><title>Fourier Transform on MacWorks</title><link>https://macworks.dev/tags/fourier-transform/</link><description>Recent content in Fourier Transform on MacWorks</description><generator>Hugo</generator><language>en</language><atom:link href="https://macworks.dev/tags/fourier-transform/index.xml" rel="self" type="application/rss+xml"/><item><title>Engineer Reads</title><link>https://macworks.dev/docs/today/engineer-blogs-2026-07-15/</link><pubDate>Mon, 01 Jan 0001 00:00:00 +0000</pubDate><guid>https://macworks.dev/docs/today/engineer-blogs-2026-07-15/</guid><description>&lt;h1 id="engineering-reads--2026-07-15"&gt;Engineering Reads — 2026-07-15&lt;a class="anchor" href="#engineering-reads--2026-07-15"&gt;#&lt;/a&gt;&lt;/h1&gt;
&lt;h2 id="the-big-idea"&gt;The Big Idea&lt;a class="anchor" href="#the-big-idea"&gt;#&lt;/a&gt;&lt;/h2&gt;
&lt;p&gt;The transition from Fourier series to the Fourier transform relies on a powerful mathematical conceptualization: expanding a signal&amp;rsquo;s repeating period to infinity to model non-repeating functions. This shift smoothly transforms discrete frequency coefficients into a continuous frequency domain, unlocking the essential mathematics behind modern signal processing and filter design.&lt;/p&gt;
&lt;h2 id="deep-reads"&gt;Deep Reads&lt;a class="anchor" href="#deep-reads"&gt;#&lt;/a&gt;&lt;/h2&gt;
&lt;p&gt;&lt;strong&gt;&lt;a href="https://eli.thegreenplace.net/2026/notes-on-the-fourier-transform/"&gt;Notes on the Fourier Transform&lt;/a&gt;&lt;/strong&gt; · eli.thegreenplace.net
This article bridges the conceptual gap between Fourier series and Fourier transforms by demonstrating what happens mathematically and visually when a function&amp;rsquo;s repeating period expands to infinity. By taking the limit as the interval grows, the frequency spacing between discrete coefficients shrinks to zero, elegantly transforming a discrete Riemann sum into the continuous integral that defines the Fourier transform. A critical tradeoff highlighted is the existence condition of absolute integrability; periodic functions are not absolutely integrable, meaning they strictly require Fourier series rather than transforms. The piece also walks through vital engineering properties, proving mathematically why time-domain convolution collapses into computationally cheap frequency-domain multiplication. Engineers working with DSP, audio programming, or partial differential equations should read this to ground their practical use of transforms in a rigorous, visual understanding of time-frequency duality.&lt;/p&gt;</description></item></channel></rss>