4. a Find the compact trigonometric Fourier series for the periodic signal x() and sketch the amplitude and phase spectrum for first 4 frequency components. By inspection of the spectra, sketch the exponential Fourier spectra. for x(t) c) By inspection of spectra in part b), write the exponential Fourier series (20 points) X(t) T/2 a/2 T/2 Solution The Fourier series is a method of expressing most periodic, time-domain functions in the frequency domain. The frequency domain representation appears graphically as a series of spikes occurring at the fundamental frequency (determined by the period of the original function) and its harmonics. The magnitudes of these spikes are the Fourier coefficients. This series of components are called the wave spectrum. THE EXPONENTIAL FOURIER SERIES å ¥ =-¥ w = n jn t n f t D e 0 ( ) where: D is the amplitude or coefficient n is the harmonic w0 is the radian frequency [rad/s] w0/2p is the frequency [hertz] T0 = 2p/w0 is the period [sec.] ò - w = 0 0 ( ) 1 0 T jn t n f t e dt T D 0 0 0 D = C = a 0 0 2 T p w = The exponential form carries no more and no less information than the other forms but is preferred because it requires less calculation to determine and also involves simpler calculations in its use. One drawback is that the exponential form is not as easy to visualize as trigonometric forms. THE TRIGONOMETRIC FOURIER SERIES å ¥ = = + w + w 1 0 0 0 ( ) cos sin n n n f t a a n t b n t where: a is the amplitude or coefficient n is the harmonic q is the phase w0 is the radian frequency [rad/s] w0/2p is the frequency [hertz] T0 = 2p/w0 is the period [sec.] ò = 0 ( ) 1 0 0 T f t dt T a 0 0 2 T p w = n n T n f t n t dt C T a = w = q ò ( ) cos cos 2 0 0 0 n n T n f t n t dt C T b = w = - q ò ( )sin sin 2 0 0 0 The Fourier series of an even periodic function will consist of cosine terms only and an odd periodic function will consist of sine terms only. Tom Penick tomzap@eden.com www.teicontrols.com/notes 2/5/2000 THE COMPACT TRIGONOMETRIC FOURIER SERIES å ¥ = = + w + q 1 0 0 ( ) cos( ) n n n f t C C n t where: C is the amplitude or coefficient n is the harmonic q is the phase w0 is the radian frequency [rad/s] w0/2p is the frequency [hertz] T0 = 2p/w0 is the period [sec.] 2 2 Cn = an + bn 0 0 C = a n n a , b : see above ÷ ÷ ø ö ç ç è æ - q = - n n n a 1 b tan 0 0 2 T p w = THE DIRICHLET CONDITIONS WEAK DIRICHLET CONDITION - For the Fourier series to exist, the function f(t) must be absolutely integrable over one period so that coefficients a0, an, and bn are finite. This guarantees the existence of a Fourier series but the series may not converge at every point. STRONG DIRICHLET CONDITIONS - For a convergent Fourier series, we must meet the weak Dirichlet condition and f(t) must have only a finite number of maxima and minima in one period. It is permissible to have a finite number of finite discontinuities in one period. FREQUENCY SPECTRA AMPLITUDE SPECTRUM - The plot of amplitude Cn versus the (radian) frequency.