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Basic Discrete Time Signals01:16

Basic Discrete Time Signals

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The unit step sequence is defined as 1 for zero and positive values of the integer n. This sequence can be graphically displayed using a set of eight sample points, showing a step function starting from n=0 and remaining constant thereafter.
The unit impulse or sample sequence is mathematically expressed as zero for all n values except at n=0, where it is one. The unit impulse sequence, denoted by δ(n), is the first difference of the unit step sequence, while the unit step sequence u(n) is the...
543
Basic Continuous Time Signals01:22

Basic Continuous Time Signals

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Basic continuous-time signals include the unit step function, unit impulse function, and unit ramp function, collectively referred to as singularity functions. Singularity functions are characterized by discontinuities or discontinuous derivatives.
The unit step function, denoted u(t), is zero for negative time values and one for positive time values, exhibiting a discontinuity at t=0. This function often represents abrupt changes, such as the step voltage introduced when turning a car's...
581
Fast Fourier Transform01:10

Fast Fourier Transform

703
The Fast Fourier Transform (FFT) is a computational algorithm designed to compute the Discrete Fourier Transform (DFT) efficiently. By breaking down the calculations into smaller, manageable sections, the FFT significantly reduces the computational complexity involved. Direct computation of an N-point DFT requires N2 complex multiplications, whereas the FFT algorithm needs only (N/2)log⁡2N multiplications, offering a much faster performance.
The computational efficiency of the FFT becomes...
703
Reconstruction of Signal using Interpolation01:10

Reconstruction of Signal using Interpolation

590
Signal processing techniques are essential for accurately converting continuous signals to digital formats and vice versa. When a continuous signal is sampled with a period T, the resulting sampled signal exhibits replicas of the original spectrum in the frequency domain, spaced at intervals equal to the sampling frequency. To handle this sampled signal, a zero-order hold method can be applied, which creates a piecewise constant signal by retaining each sample's value until the next...
590
Convolution: Math, Graphics, and Discrete Signals01:24

Convolution: Math, Graphics, and Discrete Signals

714
In any LTI (Linear Time-Invariant) system, the convolution of two signals is denoted using a convolution operator, assuming all initial conditions are zero. The convolution integral can be divided into two parts: the zero-input or natural response and the zero-state or forced response, with t0 indicating the initial time.
To simplify the convolution integral, it is assumed that both the input signal and impulse response are zero for negative time values. The graphical convolution process...
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Discrete-Time Fourier Series01:20

Discrete-Time Fourier Series

535
The Discrete-Time Fourier Series (DTFS) is a fundamental concept in signal processing, serving as the discrete-time counterpart to the continuous-time Fourier series. It allows for the representation and analysis of discrete-time periodic signals in terms of their frequency components. Unlike its continuous counterpart, which utilizes integrals, the calculation of DTFS expansion coefficients involves summations due to the discrete nature of the signal.
For a discrete-time periodic signal x[n]...
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Related Experiment Video

Updated: Dec 7, 2025

Retrospective Cardiac Gating with A Prototype Small-Animal X-ray Computed Tomograph
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Fast Recursive Computation of Sliding DHT with Arbitrary Step.

Vitaly Kober1,2,3

  • 1Department of Computer Science, CICESE, Ensenada 22860, Mexico.

Sensors (Basel, Switzerland)
|October 1, 2020
PubMed
Summary
This summary is machine-generated.

A new fast algorithm speeds up spectral analysis for quasi-stationary signals using the discrete Hartley transform (DHT). This method efficiently computes the DHT in equidistant windows, improving computational performance for applications like audio and biomedical signal processing.

Keywords:
discrete Hartley transformsensor noise removalshort-time transformsignal processingsliding algorithm

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Area of Science:

  • Signal Processing
  • Spectral Analysis
  • Computational Mathematics

Background:

  • Short-time transforms, particularly the discrete Hartley transform (DHT), are crucial for estimating power spectra in quasi-stationary signals.
  • Sliding window techniques are commonly employed, but efficiency can be improved by increasing the step size for signals with slowly varying spectra.

Discussion:

  • This study introduces a novel fast algorithm for computing the discrete Hartley transform (DHT) in equidistant windows.
  • The algorithm leverages a second-order recursive relation between local transform spectra for enhanced computational efficiency.
  • Performance is evaluated against existing fast Hartley transform and sliding window algorithms.

Key Insights:

  • A computationally efficient algorithm for equidistant DHT computation is presented.
  • The recursive relation significantly reduces computational complexity for spectral analysis.
  • The proposed method offers a performance advantage over traditional sliding window approaches.

Outlook:

  • This algorithm has potential applications in real-time spectral analysis of speech, audio, radar, communication, and biomedical signals.
  • Further research could explore adaptive windowing strategies to optimize performance for non-stationary signals.
  • Optimization for hardware implementation could further enhance its practical utility.