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Signals and Systems EE235 Lecture 21 Leo Lam © 2010-2012.

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Presentation on theme: "Signals and Systems EE235 Lecture 21 Leo Lam © 2010-2012."— Presentation transcript:

1 Signals and Systems EE235 Lecture 21 Leo Lam ©

2 It’s here! Solve Given Solve Leo Lam ©

3 Today’s menu Fourier Series Leo Lam ©

4 Trigonometric Fourier Series
Note a change in index Set of sinusoids: fundamental frequency w0 4 Leo Lam ©

5 Trigonometric Fourier Series
Orthogonality check: for m,n>0 5 Leo Lam ©

6 Trigonometric Fourier Series
Similarly: Also true: prove it to yourself at home: 6 Leo Lam ©

7 Trigonometric Fourier Series
Find coefficients: The average value of f(t) over one period (DC offset!) 7 Leo Lam ©

8 Trigonometric Fourier Series
Similarly for: 8 Leo Lam ©

9 Compact Trigonometric Fourier Series
Instead of having both cos and sin: Recall: Expand and equate to the LHS Harmonic Addition Theorem 9 Leo Lam ©

10 Compact Trigonometric to est
In compact trig. form: Remember goal: Approx. f(t)Sum of est Re-writing: And finally: Writing signals in terms of exponentials 10 Leo Lam ©

11 Compact Trigonometric to est
Most common form Fourier Series Orthonormal: , Coefficient relationship: dn is complex: Angle of dn: Angle of d-n: Writing signals in terms of exponentials 11 Leo Lam ©

12 So for dn We want to write periodic signals as a series: And dn:
Need T and w0 , the rest is mechanical 12 Leo Lam ©

13 Harmonic Series Building periodic signals with complex exp.
Obvious case: sums of sines and cosines Find fundamental frequency Expand sinusoids into complex exponentials (“CE’s”) Write CEs in terms of n times the fundamental frequency Read off cn or dn Writing signals in terms of exponentials 13 Leo Lam ©

14 Harmonic Series Example: Expand: 14 Fundamental freq.
Writing signals in terms of exponentials 14 Leo Lam ©

15 Harmonic Series Example: Fundamental frequency: Re-writing: 15
w0=GCF(1,2,5)=1 or Re-writing: Writing signals in terms of exponentials dn = 0 for all other n 15 Leo Lam ©

16 Harmonic Series Example (your turn):
Write it in an exponential series: d0=-5, d2=d-2=1, d3=1/2j, d-3=-1/2j, d4=1 Writing signals in terms of exponentials 16 Leo Lam ©

17 Harmonic Series Graphically: 17 One period: t1 to t2 All time
(zoomed out in time) 17 Leo Lam ©

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