ποΈ Prerequisite Theory
This section assumes familiarity with the below:
ποΈ Keywords & Conventions
Keywords
ποΈ Introduction
Fourier techniques let us express any signal as a sum of its constituent "pure" sinusoids (frequencies), meaning:
ποΈ Fourier Series - the bridge (periodic signals)
The Fourier Series decomposes a periodic signal in the time domain into a sum of harmonics -
ποΈ Continuous Fourier Transform
If you take the Fourier series and let the period $T \to \infty$, the discrete harmonic lines become continuous β resulting in the Continuous Fourier Transform (CFT).
ποΈ Discrete-time signals and the DFT
When we sample a continuous-time signal at a sampling rate $f_s$ (in Hz), or when we work with inherently discrete data (such as digital audio or images),
ποΈ How Fourier Transforms Work
To understand how Fourier transforms work βunder the hoodβ, we must start by
ποΈ Sign of the Exponent in the Fourier Kernel and Its Relationship to Rotational Direction
In the Fourier transform, the kernel contains a complex exponential of the form:
ποΈ Relationship Between the Fourier Series and the Continuous and Discrete Fourier Transforms
- Fourier series: discrete frequencies for periodic continuous signals
ποΈ Why Img2Num Uses the DFT
1. Inputs are digital β images and arrays are sampled and finite; the DFT exactly models the transform we can compute on them.
ποΈ Fourier Cheat Sheet
Core identities