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Continuous-time Signals ELEC 309 Prof. Siripong Potisuk.

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Presentation on theme: "Continuous-time Signals ELEC 309 Prof. Siripong Potisuk."— Presentation transcript:

1 Continuous-time Signals ELEC 309 Prof. Siripong Potisuk

2 Signal Transformations Operations Performed on the Independent and Dependent Variables 1) Reflection or Time Reversal or Folding 2) Time Shifting 3) Time Scaling 4) Amplitude Scaling 5) Amplitude Shifting Note: The independent variable is assumed to be t representing time.

3 Time reversal or Folding or Reflection about t = 0 For CT signals, replace t by –t x(-t) is the reflected version of x(t) obtained from x(t) by a reflection about t =0

4 Time Shifting (Advance or Delay)

5 Time Scaling

6 Amplitude Scaling Multiply x(t) by A, where A is the scaling factor If A is negative, the original signal x(t) is also reflected about the horizontal axis.

7 Amplitude Shifting Add a constant A to x(t), where A is the amount of shift (upward or downward)

8 Signal Characteristics Deterministic vs. Random Finite-length vs. Infinite-length Right-sided/ Left-sided/ Two-sided Causal vs. Anti-causal Periodic vs. Aperiodic (Non-periodic) Real vs. Complex Conjugate-symmetric vs. Conjugate-antisymmetric Even vs. Odd

9 Even & Odd CT Signals A complex-valued signal x(t) is said to be A real-valued signal x(t) is said to be

10 Even-Odd Signal Decomposition A CT signal can be decomposed into its even and odd parts.

11 CT Periodic Signals A CT periodic signal x(t) is a function of time that satisfies the condition T is a positive constant T 0 is the smallest value of T called the fundamental period of x(t) f 0 = 1/T 0 called the fundamental frequency  0 = 2  f 0 called the angular frequency

12 A Sum of CT Periodic Signals

13 CT Aperiodic (nonperiodic) Signals Does not satisfy the condition Periodic extension accomplished by using summation and time-shifting operation

14 Signal Metrics Energy Power Magnitude Area

15 Energy An infinite-length signal with finite amplitude may or may not have finite energy. A finite-length signal with finite amplitude have finite energy.

16 Power A finite energy signal with zero average power is called an ENERGY signal. An infinite energy signal with finite average power is called a POWER signal.

17 Average Power Average over one period for periodic signal, e.g., Root-mean-square power:

18 Magnitude & Area

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