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LECTURE 11: FOURIER TRANSFORM PROPERTIES

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Presentation on theme: "LECTURE 11: FOURIER TRANSFORM PROPERTIES"— Presentation transcript:

1 LECTURE 11: FOURIER TRANSFORM PROPERTIES
Objectives: Linearity Time Shift and Time Reversal Multiplication Integration Convolution Parseval’s Theorem Duality Resources: BEvans: Fourier Transform Properties MIT 6.003: Lecture 8 DSPGuide: Fourier Transform Properties Wiki: Audio Timescale Modification ISIP: Spectrum Analysis MS Equation 3.0 was used with settings of: 18, 12, 8, 18, 12. URL:

2 Linearity Recall our expressions for the Fourier Transform and its inverse: The property of linearity: Proof: (synthesis) (analysis)

3 Time Shift Time Shift: Proof:
Note that this means time delay is equivalent to a linear phase shift in the frequency domain (the phase shift is proportional to frequency). We refer to a system as an all-pass filter if: Phase shift is an important concept in the development of surround sound.

4 Time Scaling Time Scaling: Proof:
Generalization for a < 0 , the negative value is offset by the change in the limits of integration. What is the implication of a < 1 on the time-domain waveform? On the frequency response? What about a > 1? Any real-world applications of this property? Hint: sampled signals.78 ]i=k,

5 Time Reversal Time Reversal: Proof:
We can also note that for real-valued signals: Time reversal is equivalent to conjugation in the frequency domain. Can we time reverse a signal? If not, why is this property useful? ]i=k,

6 Multiplication by a Power of t
Proof: We can repeat the process for higher powers of t. ]i=k,

7 Multiplication by a Complex Exponential (Modulation)
Proof: Why is this property useful? First, another property: This produces a translation in the frequency domain. How might this be useful in a communication system? ]i=k,

8 Differentiation / Integration
Differentiation in the Time Domain: Integration in the Time Domain: What are the implications of time-domain differentiation in the frequency domain? Why might this be a problem? Hint: additive noise. How can we apply these properties? Hint: unit impulse, unit step, … ]i=k,

9 Convolution in the Time Domain
Proof: ]i=k,

10 Other Important Properties
Multiplication in the time domain: Parseval’s Theorem: Duality: Note: please read the textbook carefully for the derivations and interpretation of these results. ]i=k,

11 Summary

12 Example: Cosine Function

13 Example: Periodic Pulse Train

14 Example: Gaussian Pulse

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