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Transcript
5/13/2017 582745316 1/5 Amplifier DC Offset We will find that many amplifiers exhibit a DC offset (i.e., a DC bias) at their output. vo Voff vi A The output of these amplifiers can be expressed as: vo t A vi t Voff where A and Voff are constants. It is evident that if the input is zero, the output voltage will not be! i.e., vo if vi 0 5/13/2017 582745316 2/5 Yikes! How do we determine the gain of such an amplifier? If: vo t A vi t Voff then what is: vo (t) ????? vi (t) The ratio of the output voltage to input voltage is not a constant! The gain of any amplifier can be defined more precisely using the derivative operator: Avo d vo d vi Thus, for an amplifier with an output DC offset, we find the voltage gain to be: d vo d Avi Voff Avo A d vi d vi In other words, the gain of an amplifier is determined by the slope of the transfer function! 5/13/2017 582745316 3/5 For an amplifier with no DC offset (i.e., vo Avo vi ), it is easy to see that the gain is likewise determined from this definition: Avo d vo d Avo vi Avo d vi d vi Hey! Hey! This definition makes sense if you think about it—gain is the change of the output voltage with respect to a change at the input. For example, of small change vi at the input will result in a change of Avo vi at the output. If Avo is large, this change at the output will be large! Problem! The derivative of the transfer curve for real amplifiers will not be a constant. We find that the gain of a amplifier will often be dependent on the input voltage! The main reason for this is amplifier saturation. Consider again the transfer function of an amplifier that saturates: L vo Avi Voff L vi > Lin Lin < vi < Lin vi < Lin 5/13/2017 582745316 4/5 We find the gain of this amplifier by taking the derivative with respect to vi : vi > Lin 0 d vo Avo A Lin < vi < Lin d vi vi < Lin 0 Graphically, this result is: Avo d vo d vi vo L+ Voff vi Lin Lin L- 5/13/2017 582745316 5/5 Thus, the gain of this amplifier when in saturation is zero. A change in the input voltage will result in no change on the output—the output voltage will simply be vo L . Again, the transition into saturation is gradual for real amplifiers. In fact, we will find that many of the amplifiers studied in this class have a transfer function that looks something like this: vo A d v d v vo o i vi We will find that the voltage gain of many amplifiers is dependent on the input voltage. Thus, a DC bias at the input of the amplifier is often required to maximize the amplifier gain.
