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From Continuous Time System to Discrete Time System ES400 Jack Ou, Ph.D. Chapter 1.

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Presentation on theme: "From Continuous Time System to Discrete Time System ES400 Jack Ou, Ph.D. Chapter 1."— Presentation transcript:

1 From Continuous Time System to Discrete Time System ES400 Jack Ou, Ph.D. Chapter 1

2 Outline Modeling – Signal – System Continuous Time System ADC Discrete Time System

3 Signals Signals are divided into two natural categories – Continuous time signal: Discrete time signal: defined at only defined for all values of time – Discrete Time Signal: Only defined at certain instants of time.

4 Example of a Continuous Time Signal Criterion: The signal defined for all values of time Techniques: Fourier series, Fourier transform, Laplace transform

5 Example of a Discrete Time Signal Criterion: The signal is defined for at only certain instants of time Technique: Z transform, DFT, FFT

6 Tinkering

7 Mathematical Modeling of a Physical System

8 Mathematical Solutions of Physical Problems 1.Formulate a math model for physical signal and system involved. 2.Equations are solved for typical excitation function. 3.Compare math solution with the response of the physical system 4.Iterate the process until close correlation between the measured and model is achieved.

9 Continuous Time Example

10 Mathematical Modeling of Elementary Circuits

11 Use KVL to formulate the mathematical representation of a physical system KVL: The algebraic sum of Voltages around any closed loop in an electric circuit is zero.

12 Describe the input signal mathematically

13 Represent Input Voltage Source using Laplace Transform

14 Solve the problem in the Laplace Domain Laplace transform the KVL expression Solve the variable of interest Inverse Laplace Transform

15 Not All Systems Can Be Represented Using a Continuous Time Representation

16 Convert a Signal From Continuous Time System to Discrete Time System Operational Amplifier Digital to Analog Converter Comparator Counter-Ramp Analog to Digital Converter

17 Operational Amplifier If used in a feedback configuration, V + =V -. Large input impedance!

18 A Simple Voltage Amplifier

19 Digital-to-analog Converter Purpose: Convert a binary number to a voltage.

20 A Simple Digital to Analog Converter Assume “1”=5V, “0”=0V D0=“1”, D1=“0”, D2=“0” What is Vout?

21 Comparator If V i >V r, then V o =“1” Else zero.

22 A Simple Op-Amp Based Comparator

23 A Analog-to-digital Converter (Inverter) (NAND) EOC: End of Conversion A binary output approximately equal to Vx will be when EOC=1

24 Sampling in Telephone Systems

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