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Analogue to Digital Conversion © D Hoult 2010 ODWSC.

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Presentation on theme: "Analogue to Digital Conversion © D Hoult 2010 ODWSC."— Presentation transcript:

1 Analogue to Digital Conversion © D Hoult 2010 ODWSC

2 analogue signal © D Hoult 2010 ODWS

3 The analogue signal must be sampled (its voltage must be measured at regular intervals). © D Hoult 2010 ODWS

4 The analogue signal must be sampled (its voltage must be measured at regular intervals). To measure the voltage, the A to D converter produces its own voltage which it increases in discrete steps until it is equal to the signal voltage. © D Hoult 2010 ODWS

5 The analogue signal must be sampled (its voltage must be measured at regular intervals). To measure the voltage, the A to D converter produces its own voltage which it increases in discrete steps* until it is equal to the signal voltage. * this voltage is said to be quantised © D Hoult 2010 ODWS

6 The analogue signal must be sampled (its voltage must be measured at regular intervals). At this point the counter is disabled (it stops counting). To measure the voltage, the A to D converter produces its own voltage which it increases in discrete steps until it is equal to the signal voltage. © D Hoult 2010 ODWS

7 V s is the value of the signal voltage at the instant of sampling © D Hoult 2010 ODWS

8 The sampling process is assumed to take a very short time. © D Hoult 2010 ODWS

9

10

11 The precision of the process is limited by the size of the steps © D Hoult 2010 ODWS

12 This depends on the number of bits used by the counter © D Hoult 2010 ODWS

13 3 bit precision and sampling frequency 1 Hz © D Hoult 2010 ODWS

14 3 bit precision and sampling frequency 1 Hz © D Hoult 2010 ODWS

15 3 bit precision and sampling frequency 1 Hz © D Hoult 2010 ODWS

16 3 bit precision and sampling frequency 1 Hz © D Hoult 2010 ODWS

17 3 bit precision and sampling frequency 1 Hz © D Hoult 2010 ODWS

18 digital signal 3 bit precision and sampling frequency 1 Hz © D Hoult 2010 ODWS

19 digital signal binary coded output 3 bit precision and sampling frequency 1 Hz © D Hoult 2010 ODWS

20 digital signal binary coded output 110 110 110 etc 3 bit precision and sampling frequency 1 Hz © D Hoult 2010 ODWS

21 3 bit precision and sampling frequency 2 Hz © D Hoult 2010 ODWS

22 3 bit precision and sampling frequency 2 Hz © D Hoult 2010 ODWS

23 3 bit precision and sampling frequency 2 Hz © D Hoult 2010 ODWS

24 digital signal binary coded output 3 bit precision and sampling frequency 2 Hz © D Hoult 2010 ODWS

25 digital signal binary coded output 110 001 110 001 etc 3 bit precision and sampling frequency 2 Hz © D Hoult 2010 ODWS

26 3 bit precision and sampling frequency 4 Hz © D Hoult 2010 ODWS

27 digital signal binary coded output 110 001 110 001 etc 3 bit precision and sampling frequency 4 Hz © D Hoult 2010 ODWS

28 4 bit precision and sampling frequency 4 Hz © D Hoult 2010 ODWS

29 4 bit precision and sampling frequency 4 Hz © D Hoult 2010 ODWS

30 binary coded output 1011 0010 1011 0010 etc 4 bit precision and sampling frequency 4 Hz © D Hoult 2010 ODWS

31 4 bit precision and sampling frequency 8 Hz © D Hoult 2010 ODWS

32 binary coded output 4 bit precision and sampling frequency 8 Hz © D Hoult 2010 ODWS

33 1011 1100 1011 0110 0010 0000 0010 0110 etc 4 bit precision and sampling frequency 8 Hz © D Hoult 2010 ODWS

34 1011 1100 1011 0110 0010 0000 0010 0110 etc Binary coded digital output corresponding to the first four samples © D Hoult 2010 ODWS

35 1011 1100 1011 0110 0010 0000 0010 0110 etc Binary coded digital output corresponding to the first four samples © D Hoult 2010 ODWS

36 1011 1100 1011 0110 0010 0000 0010 0110 etc Binary coded digital output corresponding to the first four samples © D Hoult 2010 ODWS

37 1011 1100 1011 0110 0010 0000 0010 0110 etc Binary coded digital output corresponding to the first four samples © D Hoult 2010 ODWS

38 1011 1100 1011 0110 0010 0000 0010 0110 etc Binary coded digital output corresponding to the first four samples © D Hoult 2010 ODWS

39 1011 1100 1011 0110 0010 0000 0010 0110 etc Binary coded digital output corresponding to the first four samples In some systems, logic 1 (true) is represented by zero volts and logic zero (false) by 5 V © D Hoult 2010 ODWS

40 1011 1100 1011 0110 0010 0000 0010 0110 etc Binary coded digital output corresponding to the first four samples In some systems, logic 1 (true) is represented by zero volts and logic zero (false) by 5 V © D Hoult 2010 ODWS

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