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16.362 Signal and System I Signal energy and power Instantaneous power Energy in time interval t1 to t2 Average power in time interval t1 to t2 Total energy.

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Presentation on theme: "16.362 Signal and System I Signal energy and power Instantaneous power Energy in time interval t1 to t2 Average power in time interval t1 to t2 Total energy."— Presentation transcript:

1 16.362 Signal and System I Signal energy and power Instantaneous power Energy in time interval t1 to t2 Average power in time interval t1 to t2 Total energy Average power over infinite period

2 16.362 Signal and System I Signal energy and power– discrete time Instantaneous power Energy in time interval N1 to N2 Average power in time interval N1 to N2 Total energy Average power over infinite period

3 16.362 Signal and System I Transform of the independent variable (1) Time-shift New point located at

4 16.362 Signal and System I Transform of the independent variable New point located at (1) Time-shift

5 16.362 Signal and System I Transform of the independent variable New point located at (2) Time-reversal

6 16.362 Signal and System I Transform of the independent variable New point located at (3) Scale

7 16.362 Signal and System I Example 1 1 2 1 1 2 1 1 2 1 1 2 -2 -2/3 2/3

8 16.362 Signal and System I Periodical signal Even and odd signals even odd Any signal has its even and odd signal part Even part Odd part

9 16.362 Signal and System I Exponential and Sinusoidal signals a>0, exponentially increase with t. Real exponential:C, and a are real numbers a<0, exponentially decrease with t. Complex exponential:C, and a are real numbers Euler’s relation:

10 16.362 Signal and System I Exponential and Sinusoidal signals Energy in one period: Average power:

11 16.362 Signal and System I Exponential and Sinusoidal signals, discrete-time a>0, exponentially increase with n. Real exponential:C, and a are real numbers a<0, exponentially decrease with n. Complex exponential:C, and a are real numbers Periodicity properties of discrete-time complex exponential:  0 has a period of 2  N has a period of 2  /  0

12 16.362 Signal and System I Example:

13 16.362 Signal and System I Discrete-time unit impulse and unit step function Unit impulse Unit step

14 16.362 Signal and System I Discrete-time unit impulse and unit step function

15 16.362 Signal and System I continuous-time unit impulse and unit step function Unit impulse Unit step

16 16.362 Signal and System I continuous-time unit impulse and unit step function

17 16.362 Signal and System I Continuous-time and discrete-time systems Continuous-time Discrete-time System diagram and properties will be discussed in later chapters.

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