m (HW3-Lectures moved to ECE438 Fall HW3) |
|||
| Line 1: | Line 1: | ||
| + | '''ECE 438 Fall Homework 3''' | ||
| + | |||
[[Image:xt.jpg]] | [[Image:xt.jpg]] | ||
[[Image:xst.jpg]] | [[Image:xst.jpg]] | ||
| Line 5: | Line 7: | ||
[[Image:xf_s.jpg]] | [[Image:xf_s.jpg]] | ||
[[Image:Xw.jpg]] | [[Image:Xw.jpg]] | ||
| − | |||
Part I: how to convert CT signals to DT signals after sampling. | Part I: how to convert CT signals to DT signals after sampling. | ||
Introduce variables: | Introduce variables: | ||
Revision as of 13:50, 22 September 2009
ECE 438 Fall Homework 3
Part I: how to convert CT signals to DT signals after sampling.
Introduce variables:
xc(t)=continuous time signal
xs(t)=signals after sampling
x[n]=discrete time signal
Background: DTFT Xd(ejw)= ∑n=-∞∞ xd[n]e-jwn; -----(1) Sampling, xs(t)=xc(t)pT(t)= ∑n=-∞∞ xc[nTs] δ(t-nTs), where pT(t)= ∑n=-∞∞ δ(t-nTs)
Xs(f)= CTFT{ ∑n=-∞∞ xc[nTs] δ(t-nTs)}
where 1. CTFT{δ(t-nTs)}=∫- ∞∞ δ(t-nTs)e-j2πftdt=e-j2πfnTs
2. xc[nTs] is a function of a variable n, and can be rewritten as x[n]
Therefore, Xs(f)= ∑n=-∞∞ x[n]e-j2πfnTs OR X(w)= ∑n=-∞∞ x[n]e-j2πwnTs -------(2)
If 2πTs=1, fs=2π, equation (2) can be rewritten as ∑n=-∞∞ x[n]e-jwn,(3)
What we can conclude from here is that: if we rescale sampling rate fs as 2π, the sampling signals- a train of impulses can be redrawn to DT signals. The complete expression is X(ejw)=Xs(w/(2πTs))=1/Ts∑n=-∞∞ Xc(w/(2πTs)-n/Ts) We rescaled the original fmax as 2πfmax/fs; also, the amplitude was fs times the initial amplitude from xs(t).
