engg 330 class 2 concepts, definitions, and basic properties
TRANSCRIPT
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ENGG 330
Class 2
Concepts, Definitions, and Basic Properties
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Quiz
• What is the difference between– Stem & Plot– How do I specify a discrete sample space from
0 to 10– How do I multiply a scalar times a matrix– How do I express e3[n]
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Remember
• Real world signals are very complex
• Can’t hope to model them
• Can model simple signals
• Can tell a lot about systems with simple signals
• Can model complex signals with, dare I say, transformations of simple signals
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Transformations of the Independent Variable
• Example Transformations
• Periodic Signals
• Even and Odd Signals
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Transformations of Signals
• A central concept is transforming a signal by the system– An audio system transforms the signal from a
tape deck
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Example Transformations
• Time Shift – Radar, Sonar, Seismic– x[n-n0] & x(t-t0)
• Notice a difference? n for D-T, t for C-T
– Delayed if t0 positive, Advanced if t0 negative
• Time Reversal – tape played backwards– x[n] becomes x[-n] by reflection about n = 0
• Time Scaling – tape played slower/faster– x(t), x(2t), x(t/2)
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Time Shift
t0 < 0 so x(t-t0) is an advanced version of x(t)
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Time Reversal
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Time Scaling
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?
What does x(t+1) look like?
When t = -2 t+1 = -1 what is x(t) at –1? 0 When t = -1 t+1 = 0 what is x(t) at 0? 1When t = 0 t+1 = 1 what is x(t) at 1? 1When t = 1 t+1 = 2 what is x(t) at 2? 0
Th e other way – t + 1+1 advanced in time
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Given x(t) what would x(t-1) look like?
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?
What does x(-t+1) look like?
When t = -1 -t+1 = 2 what is x(t) at 2? 0When t = 0 -t+1 = 1 what is x(t) at 1? 1When t = 1 -t+1 = 0 what is x(t) at 0? 1When t = 2 -t+1 = -1 what is x(t) at –1? 0
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The other wayx(-t + 1)
Apply the +1 time shift
Apply the –t reflection about the y axis
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?
What does x(3 /2 t) look like?
When t = -1 3t/2 = -3/2 what is x(t) at -3/2? 0When t = 0 3t/2 = 0 what is x(t) at 0? 1When t = 1 3t/2 = 3/2 what is x(t) at 3/2? ?When t = 2/3 3t/2 = 1 what is x(t) at 1? 1Why 2/3?What is the next t that should be evaluated?4/3 why?
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?
What does look like?
Next apply the 3t/2 and compress the signal
First apply the +1 and advance the signal
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Signal Transformations
• X(at + b) where a and b are given numbers– Linearly Stretched if |a| < 1– Linearly Compressed if |a| > 1– Reversed if a < 0– Shifted in time if b is nonzero
• Advanced in time if b > 0
• Delayed in time if b < 0
• But watch out for x(-2t/3 + 1)
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Periodic Signals
• x(t) = x(t + T) x(t) periodic with period T
• x[n] = x[n + N] periodic with period N
• Fundamental period T or N
• Aperiodic
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Even and Odd Signals
• Even signals – x(-t) = x(t)– x[-n] = x[n]
• Odd signals – x(-t) = -x(t)– x[-n] = -x[n]– Must be 0 at t = 0 or n = 0
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• Any signal can be broken into a sum of two signals on even and one odd– Ev{x(t)} = ½[x(t) + x(-t)]– Od{x(t)} = ½[x(t) – x(-t)]
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Exponential and Sinusoidal Signals
• C-T Complex Exponential and Sinusoidal Signals
• D-T Complex Exponential and Sinusoidal Signals
• Periodicity Properties of D-T Complex Exponentials
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C-T Complex Exponential and Sinusoidal Signals
• x(t) = Ceat where C and a are complex numbers– Complex number
• a + jb – rectangular form
• Rejθ – polar form
• Depending on Values of C and a Complex Exponentials exhibit different characteristics– Real Exponential Signals– Periodic Complex Exponential and Sinusoidal Signals– General Complex Exponential Signals
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Real Exponential Signals• If C and a are real
– x(t) = Ceat then called real exponential
• If a is positive x(t) is a growing exponential• If a is negative x(t) is a decaying exponential• If a 0 x(t) is a constant
– That depends upon the value of C
• Use MATLAB to plot – e2n, e-2n , e0n , 3e0n
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Periodic Complex Exponential and Sinusoidal Signals
• If a is purely imaginary– x(t) is then periodic
• x(t) = ejw0t – Plot via MATLAB
• ? j is needed to make a imaginary
• a closely related signal is Sinusoid
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General Complex Exponential Signals
• Most general case of complex exponential– Can be expressed in terms of the two cases we
have examined so far
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Periodicity Properties of D-T Complex Exponentials
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Unit Impulse and Unit Step Functions
• D-T Unit Impulse and Unit Step Functions
• C-T Unit Impulse and Unit Step Functions
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C-T & D-T Systems
• Simple Examples
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Basic System Properties
• Memory
• Inverse
• Causality
• Stability
• Time Invariance
• Linearity
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Memory
• Memoryless output for each value of independent variable is dependent on the input at only that same time
• Memoryless– y(t) = x(t), y[n]= 2x[n] – x2[2n]
• Memory– Y[n] = Σx[k], y[n] = x[n-1]
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Inverse
• Invertible if distinct inputs lead to distinct outputs
• Think of an encoding system– It must be invertible
• Think of a JPEG compression system– It isn’t invertible
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Causality
• A system is causal if the output at any time depends on values of the input at only present and past times.
• See Fowler Note Set 5 System Properties
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Stability
• If the input to a stable system is bounded the the output must also be bounded– Balanced stick
• Slight push is bounded
• Is the output bounded
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Time Invariance
• See Fowler Note Set 5 System Properties
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Linearity
• See Fowler Note Set 5 System Properties
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Assignment
• Read Chapter 1 of Oppenheim– Generate math questions for Dr. Olson
• Buck– Section 1.2 a, b, c, d– Section 1.3 a, b, c– Section 1.4 a, b
• Turn in .m files– All plots/stems need titles and xy labels– Answers to questions documented in .m file with
references to plots/stems