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Properties of DTFT I

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In signal processing, Discrete-Time Fourier Transforms (DTFTs) play a critical role in analyzing discrete-time signals in the frequency domain. Various properties of the DTFTs such as linearity, time-shifting, frequency-shifting, time reversal, conjugation, and time scaling help understand and manipulate these signals for different applications.
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Transformations of Functions II01:29

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Transformations in mathematics alter the position or orientation of a function’s graph while preserving its fundamental shape. One important type of transformation is the horizontal shift, which involves modifying the input variable within a function’s equation. This operation affects where outputs occur along the horizontal axis but does not alter the function’s overall structure.A horizontal shift is achieved by replacing the input variable x with either x + c or x - c,...
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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.
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The frequency-domain technique, commonly used in analyzing and designing feedback control systems, is effective for linear, time-invariant systems. However, it falls short when dealing with nonlinear, time-varying, and multiple-input multiple-output systems. The time-domain or state-space approach addresses these limitations by utilizing state variables to construct simultaneous, first-order differential equations, known as state equations, for an nth-order system.
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The Discrete-Time Fourier Transform (DTFT) is an essential mathematical tool for analyzing discrete-time signals, converting them from the time domain to the frequency domain. This transformation allows for examining the frequency components of discrete signals, providing insights into their spectral characteristics. In the DTFT, the continuous integral used in the continuous-time Fourier transform is replaced by a summation to accommodate the discrete nature of the signal.
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The z-transform is a powerful tool for analyzing practical discrete-time systems, often represented by linear difference equations. Solving a higher-order difference equation requires knowledge of the input signal and the initial conditions up to one term less than the order of the equation.
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Delayformer: Spatiotemporal Transformation for Predicting High-Dimensional Dynamics.

Zijian Wang1, Peng Tao1, Luonan Chen1,2,3

  • 1Key Laboratory of Systems Health Science of Zhejiang Province, School of Life Science, Hangzhou Institute for Advanced Study, University of Chinese Academy of Sciences, Chinese Academy of Sciences, Hangzhou, 310024, China.

Advanced Science (Weinheim, Baden-Wurttemberg, Germany)
|November 21, 2025
PubMed
Summary
This summary is machine-generated.

Delayformer enhances time series prediction by treating system states as delay-embedded vectors. This novel approach effectively handles nonlinearity and complex interactions in high-dimensional data.

Keywords:
delay embeddingfoundation modelnonlinearityspatiotemporal information transformationtime‐series forecastingtransformer

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Area of Science:

  • Dynamical Systems
  • Machine Learning
  • Time Series Analysis

Background:

  • Accurate time series prediction is crucial across scientific fields.
  • High-dimensional systems present challenges due to nonlinearity and complex variable interactions, especially with limited, noisy data.

Purpose of the Study:

  • Introduce the Delayformer framework for simultaneous prediction of all variables in high-dimensional time series.
  • Develop a novel multivariate spatiotemporal information (mvSTI) transformation to address prediction challenges.

Main Methods:

  • Utilize delay embedding theory to transform observed variables into delay-embedded states (vectors).
  • Employ a shared Visual Transformer (ViT) encoder for cross-representation of dynamical states.
  • Implement distinct linear decoders for parallel prediction of next states, effectively forecasting all original variables.

Main Results:

  • Delayformer demonstrates superior performance over state-of-the-art methods on synthetic and real-world datasets.
  • The framework successfully overcomes nonlinearity and cross-interaction problems by predicting system states.
  • Achieved high accuracy in forecasting tasks, outperforming existing approaches.

Conclusions:

  • Delayformer offers a robust solution for multivariate time series prediction, even with limited and noisy data.
  • The model's ability to predict system states provides theoretical and computational advantages.
  • Demonstrated broad applicability across various scenarios through cross-domain forecasting tasks.