Lectures related to Spectral leakage

Fast Fourier Transform (FFT): Basics and Applications

Covers the Fast Fourier Transform (FFT) algorithm and its applications in computational physics, including image processing, experimental techniques, filters, and analysis of microscopy images.

Relationships between transforms

Explores the relationships between various transforms and signal embedding techniques.

Signals & Systems II: Fourier Transform Properties

Explores the properties of the Discrete-Time Fourier Transform in signal processing.

Signals & Systems II: Fourier Transform and FFT

Explores Fourier Transform, FFT algorithms, DFT implementation cost, and frequency division for efficient computation.

Fast Fourier Transform (FFT): Lecture 4

Covers the Fast Fourier Transform (FFT) algorithm, interpolation, filters, image processing, and experimental techniques in TEM and STM.

Fourier Transform and Windowing

Explores spectral leakage, window functions, Fourier transforms, image processing, experimental techniques, and graphene materials.

DTFT Properties and Frequency Response Analysis

Explores DTFT properties, frequency response analysis, and the ideal low-pass filter in signal processing.

Karplus-Strong revisited and the DTFT

Explores the Karplus-Strong algorithm with decay and the DTFT of signals.

Difference Equations

Covers the concept of difference equations and properties of causal vs. stable systems.

DTFT Properties

Covers the properties of the Discrete-Time Fourier Transform, including linearity, shifts, time reversal, differentiation, convolution, conjugate symmetry, and Parseval's Relation.

Signals & Systems II: Filter Implementations

Explores IIR filter implementations, canonical vs. non-canonical forms, stability, DTFT properties, and eigenvectors in LID systems.

Geometric Response in LTI Systems

Explains geometric response in LTI systems and its relationship with impulse response.

Discrete Signals & Fourier Transform

Explores discrete signals, Fourier transform, modulation, convolution, DFT properties, and signal periodicity.

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Discrete-Time Fourier Transform

Explores the discrete-time Fourier transform, its properties, and signal transformations, including examples like the rectangular pulse and unit impulse.

Signals & Systems I: Sampling and Reconstruction

Explores ideal sampling, Fourier transformation, spectral repetition, and analog signal reconstruction.

The Window Method: Understanding and Proof of Modulation Theorem

Covers the Gibbs phenomenon, modulation theorem, convolution, and sinusoidal modulation.

Signals, Frequencies and Bandwidth

Introduces signals, frequencies, and bandwidth, including pure sinusoids, Fourier theory, and spectral representation.

Frequency Response: Examples

Covers examples of frequency response analysis, including phase analysis, linear phase, and Karplus-Strong algorithm.

Signal Processing: Fourier Transform and Fast Algorithm

Explores DTFT, DFT, FFT properties, and the cost analysis of fast algorithms.