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Published byMarshall Miller Modified over 9 years ago
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Fourier Series
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Introduction Decompose a periodic input signal into primitive periodic components. A periodic sequence T2T3T t f(t)f(t)
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Synthesis DC Part Even Part Odd Part T is a period of all the above signals Let 0 =2 /T.
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Decomposition
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Example (Square Wave) 2 3 4 5 -- -2 -3 -4 -5 -6 f(t)f(t) 1
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Example (Square Wave)
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Harmonics DC Part Even Part Odd Part T is a period of all the above signals
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Harmonics Define, called the fundamental angular frequency. Define, called the n-th harmonic of the periodic function.
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Harmonics
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Amplitudes and Phase Angles harmonic amplitudephase angle
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Complex Form of Fourier Series
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Complex Exponentials
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Complex Form of the Fourier Series
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If f(t) is real,
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Example t f(t)f(t) A
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40 80 120 -40 0 -120 -80 A/5 5050 10 0 15 0 -5 0 -10 0 -15 0
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Example 40 80 120 -40 0 -120 -80 A/10 10 0 20 0 30 0 -10 0 -20 0 -30 0
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Example t f(t)f(t) A 0
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Waveform Symmetry Even Functions Odd Functions
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Decomposition Any function f(t) can be expressed as the sum of an even function f e (t) and an odd function f o (t). Even Part Odd Part
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Example Even Part Odd Part
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Half-Wave Symmetry and TT/2 T/2
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Quarter-Wave Symmetry Even Quarter-Wave Symmetry TT/2 T/2 Odd Quarter-Wave Symmetry T T/2 T/2
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Hidden Symmetry The following is a asymmetry periodic function: Adding a constant to get symmetry property. A T TT A/2 A/2 T TT
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Fourier Coefficients of Symmetrical Waveforms The use of symmetry properties simplifies the calculation of Fourier coefficients. – Even Functions – Odd Functions – Half-Wave – Even Quarter-Wave – Odd Quarter-Wave – Hidden
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Fourier Coefficients of Even Functions
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Fourier Coefficients for Half-Wave Symmetry and TT/2 T/2 The Fourier series contains only odd harmonics.
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Fourier Coefficients for Half-Wave Symmetry and
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Fourier Coefficients for Even Quarter-Wave Symmetry TT/2 T/2
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Fourier Coefficients for Odd Quarter-Wave Symmetry T T/2 T/2
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Example Even Quarter-Wave Symmetry T T/2 T/2 1 11 TT T/4 T/4
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Example Even Quarter-Wave Symmetry T T/2 T/2 1 11 TT T/4 T/4
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Example T T/2 T/2 1 11 TT T/4 T/4 Odd Quarter-Wave Symmetry
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Example T T/2 T/2 1 11 TT T/4 T/4 Odd Quarter-Wave Symmetry
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Dirichlet Conditions A periodic signal x(t), has a Fourier series if it satisfies the following conditions: absolutely integrable 1.x(t) is absolutely integrable over any period, namely finite number of maxima and minima 2.x(t) has only a finite number of maxima and minima over any period finite number of discontinuities 3.x(t) has only a finite number of discontinuities over any period
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We have seen that periodic signals can be represented with the Fourier series aperiodic signals Can aperiodic signals be analyzed in terms of frequency components? Yes, and the Fourier transform provides the tool for this analysis spectra of aperiodic signals The major difference w.r.t. the line spectra of periodic signals is that the spectra of aperiodic signals are defined for all real values of the frequency variable not just for a discrete set of values Fourier Transform
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Fourier transform Given a signal x(t), its Fourier transform is defined as A signal x(t) is said to have a Fourier transform in the ordinary sense if the above integral converges The Fourier Transform in the General Case
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The integral does converge if well-behaved 1.the signal x(t) is “well-behaved” absolutely integrable 2.and x(t) is absolutely integrable, namely, well behaved Note: well behaved means that the signal has a finite number of discontinuities, maxima, and minima within any finite time interval The Fourier Transform in the General Case – Cont’d
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Consider Since in general is a complex function, by using Euler’s formula Rectangular Form of the Fourier Transform
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can be expressed in a polar form as where Polar Form of the Fourier Transform
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If x(t) is real-valued, it is Moreover whence Fourier Transform of Real-Valued Signals Hermitian symmetry
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Consider the even signal It is Example: Fourier Transform of the Rectangular Pulse
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Example: Fourier Transform of the Rectangular Pulse – Cont’d
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amplitude spectrum phase spectrum
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bandlimited B bandwidth of the signal A signal x(t) is said to be bandlimited if its Fourier transform is zero for all where B is some positive number, called the bandwidth of the signal It turns out that any bandlimited signal must have an infinite duration in time, i.e., bandlimited signals cannot be time limited Bandlimited Signals
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infinite bandwidthinfinite spectrum If a signal x(t) is not bandlimited, it is said to have infinite bandwidth or an infinite spectrum Time-limited signals cannot be bandlimited and thus all time-limited signals have infinite bandwidth However, for any well-behaved signal x(t) it can be proven that whence it can be assumed that Bandlimited Signals – Cont’d B being a convenient large number
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inverse Fourier transform Given a signal x(t) with Fourier transform, x(t) can be recomputed from by applying the inverse Fourier transform given by Transform pair Transform pair Inverse Fourier Transform
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Properties of the Fourier Transform Linearity: Linearity: Left or Right Shift in Time: Left or Right Shift in Time: Time Scaling: Time Scaling:
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Properties of the Fourier Transform Time Reversal: Time Reversal: Multiplication by a Power of t: Multiplication by a Power of t: Multiplication by a Complex Exponential: Multiplication by a Complex Exponential:
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Properties of the Fourier Transform Multiplication by a Sinusoid (Modulation): Multiplication by a Sinusoid (Modulation): Differentiation in the Time Domain: Differentiation in the Time Domain:
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Properties of the Fourier Transform Integration in the Time Domain: Integration in the Time Domain: Convolution in the Time Domain: Convolution in the Time Domain: Multiplication in the Time Domain: Multiplication in the Time Domain:
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Properties of the Fourier Transform Parseval’s Theorem: Parseval’s Theorem: Duality: Duality: if
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Properties of the Fourier Transform - Summary
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Example: Linearity
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Example: Time Shift
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Example: Time Scaling time compression frequency expansion time expansion frequency compression
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Example: Multiplication in Time
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Example: Multiplication by a Sinusoid sinusoidal burst
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Example: Multiplication by a Sinusoid – Cont’d
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Example: Multiplication in Time
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Example: Multiplication by a Sinusoid sinusoidal burst
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Example: Multiplication by a Sinusoid – Cont’d
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Example: Integration in the Time Domain
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Example: Integration in the Time Domain – Cont’d The Fourier transform of x(t) can be easily found to be Now, by using the integration property, it is
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Example: Integration in the Time Domain – Cont’d
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Fourier transform of Applying the duality property Generalized Fourier Transform generalized Fourier transform generalized Fourier transform of the constant signal
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Generalized Fourier Transform of Sinusoidal Signals
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Fourier Transform of Periodic Signals Let x(t) be a periodic signal with period T; as such, it can be represented with its Fourier transform Since, it is
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Since using the integration property, it is Fourier Transform of the Unit-Step Function
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Common Fourier Transform Pairs
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Laplace Transform
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Why use Laplace Transforms? Find solution to differential equation using algebra Relationship to Fourier Transform allows easy way to characterize systems No need for convolution of input and differential equation solution Useful with multiple processes in system
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How to use Laplace Find differential equations that describe system Obtain Laplace transform Perform algebra to solve for output or variable of interest Apply inverse transform to find solution
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How to use Laplace Find differential equations that describe system Obtain Laplace transform Perform algebra to solve for output or variable of interest Apply inverse transform to find solution
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What are Laplace transforms? t is real, s is complex! Inverse requires complex analysis to solve Note “transform”: f(t) F(s), where t is integrated and s is variable Conversely F(s) f(t), t is variable and s is integrated Assumes f(t) = 0 for all t < 0
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Evaluating F(s) = L{f(t)} Hard Way – do the integral let
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Evaluating F(s)=L{f(t)}- Hard Way remember let Substituting, we get: It only gets worse…
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Table of selected Laplace Transforms
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More transforms
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Note on step functions in Laplace Unit step function definition: Used in conjunction with f(t) f(t)u(t) because of Laplace integral limits:
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Properties of Laplace Transforms Linearity Scaling in time Time shift “frequency” or s-plane shift Multiplication by t n Integration Differentiation
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Properties of Laplace Transforms Linearity Scaling in time Time shift “frequency” or s-plane shift Multiplication by t n Integration Differentiation
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Properties: Linearity Example :Proof :
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Example :Proof : let Properties: Scaling in Time
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Properties: Time Shift Example :Proof : let
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Properties: S-plane (frequency) shift Example :Proof :
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Properties: Multiplication by t n Example :Proof :
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The “D” Operator 1.Differentiation shorthand 2.Integration shorthand if then if
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Properties: Integrals Example : Proof : let If t=0, g(t)=0 forso slower than
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Properties: Derivatives (this is the big one) Example :Proof : let
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The Inverse Laplace Transform
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Inverse Laplace Transforms Background: To find the inverse Laplace transform we use transform pairs along with partial fraction expansion: F(s) can be written as; Where P(s) & Q(s) are polynomials in the Laplace variable, s. We assume the order of Q(s) P(s), in order to be in proper form. If F(s) is not in proper form we use long division and divide Q(s) into P(s) until we get a remaining ratio of polynomials that are in proper form.
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Inverse Laplace Transforms Background: There are three cases to consider in doing the partial fraction expansion of F(s). Case 1: F(s) has all non repeated simple roots. Case 2: F(s) has complex poles: Case 3: F(s) has repeated poles. (expanded)
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Inverse Laplace Transforms Case 1: Illustration: Given: Find A 1, A 2, A 3 from Heavyside
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Inverse Laplace Transforms Case 3: Repeated roots. When we have repeated roots we find the coefficients of the terms as follows:
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Inverse Laplace Transforms Case 3: Repeated roots.Example ???
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Inverse Laplace Transforms Complex Roots: An Example. For the given F(s) find f(t)
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Inverse Laplace Transforms Complex Roots: An Example. (continued) We then have; Recalling the form of the inverse for complex roots;
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