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8: Continuous Time Fourier Transform (CTFT)

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    • 8.1: Continuous Time Aperiodic Signals
      This page details the application of the Continuous Time Fourier Transform to continuous-time signals, highlighting the difference between periodic and aperiodic signals. It explains that periodic functions repeat after a set period, whereas aperiodic functions do not. Furthermore, it notes that aperiodic functions can be transformed into periodic forms for analysis through infinite sums, allowing for a comprehensive examination of their frequency content.
    • 8.2: Continuous Time Fourier Transform (CTFT)
      This page covers the derivation of the Continuous Time Fourier Transform (CTFT) for continuous-time functions, emphasizing that complex exponentials serve as eigenfunctions in linear time-invariant systems. It discusses the representation of non-periodic signals and the synthesis of functions using sinusoids.
    • 8.3: Common Fourier Transforms
      This page outlines the properties of the Continuous-Time Fourier Transform (CTFT), presenting time-domain signals and their frequency-domain representations. It covers various functions, including exponential, delta, sine, cosine, and unit step functions, along with specific conditions for some signals (e.g., \( a > 0 \)). The table format provides a clear overview of the relationship between the time and frequency domains, aiding in signal analysis.
    • 8.4: Properties of the CTFT
      This page covers essential properties of the Continuous-Time Fourier Transform (CTFT), including linearity, symmetry, time scaling, shifting, convolution, differentiation, Parseval's relation, and modulation. It explains how linear combinations of signals preserve linearity in transforms, links time-domain and frequency-domain concepts, and discusses the impact of time shifts and scaling.
    • 8.5: Continuous Time Convolution and the CTFT
      This page discusses the convolution of continuous signals in time and frequency domains, introducing the Continuous Time Fourier Transform (CTFT) and its inverse. It explains the convolution integral, illustrating how the output of a linear time-invariant system is derived from the input signal and the system's impulse response. Additionally, the Convolution Theorem is highlighted, showing that convolution in one domain corresponds to multiplication in another.

    This page titled 8: Continuous Time Fourier Transform (CTFT) is shared under a CC BY 3.0 license and was authored, remixed, and/or curated by Richard Baraniuk et al. via source content that was edited to the style and standards of the LibreTexts platform.