Skip to content Skip to navigation

Connexions

You are here: Home » Content » Lab 2: Prelab (Part 1)

Navigation

Content Actions
  • Download module PDF
  • Add to ...
    Add the module to:
    • My Favorites
    • A lens
    • An external social bookmarking service
    • My Favorites (What is 'My Favorites'?)
      'My Favorites' is a special kind of lens which you can use to bookmark modules and collections directly in Connexions. 'My Favorites' can only be seen by you, and collections saved in 'My Favorites' can remember the last module you were on. You need a Connexions account to use 'My Favorites'.
    • A lens (What is a lens?)

      Definition of a lens

      Lenses

      A lens is a custom view of Connexions content. You can think of it as a fancy kind of list that will let you see Connexions through the eyes of organizations and people you trust.

      What is in a lens?

      Lens makers point to Connexions materials (modules and collections), creating a guide that includes their own comments and descriptive tags about the content.

      Who can create a lens?

      Any individual Connexions member, a community, or a respected organization.

    • External bookmarks
  • E-mail the authors

Recently Viewed

Lab 2: Prelab (Part 1)

Module by: Thomas Shen, Douglas L. Jones Based on: Multirate Filtering: Theory Exercise by Douglas L. Jones, Swaroop Appadwedula, Matthew Berry, Mark Haun, Jake Janovetz, Michael Kramer, Dima Moussa, Daniel Sachs, Brian Wade

Summary: You will work through an example problem that explores the effects of sample-rate compression and expansion on the spectrum of a signal.

Multirate Theory Exercise

Consider a sampled signal with the DTFT Xω X ω shown in Figure 1.

Figure 1: DTFT of the input signal.
Figure 1 (prelab_input.png)

Assuming U=D=3 U D 3 , use the relations between the DTFT of a signal before and after sample-rate compression and expansion (Equation 1 and Equation 2) to sketch the DTFT response of the signal as it passes through the multirate system of Figure 2 (without any filtering). Include both the intermediate response Wω W ω and the final response Yω Y ω . It is important to be aware that the translation from digital frequency ω ω to analog frequency depends on the sampling rate. Therefore, the conversion is different for Xω X ω and Wω W ω .

Wω=1Dk=0D-1Xω+2πkD W ω 1 D k 0 D 1 X ω 2 k D (1)
Yω=WUω Y ω W U ω (2)
Figure 2: Multirate System
Figure 2 (prelab_sys.png)

Comments, questions, feedback, criticisms?

Send feedback