Key Facts from Reading: Difference between revisions
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<math>\ G_{db}=10 log |A_v|+10 log R_i - 10 log R_L</math> |
<math>\ G_{db}=10 log |A_v|+10 log R_i - 10 log R_L</math> |
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*By the equation above, we can say voltage gain in decibels |
*By the equation above, we can say voltage gain in decibels can be found with this equation: <math>\ A_{v dB}=20 log |A_v|</math>, where <math>\ A_v</math> is the voltage gain and <math>\ A_{v dB}</math> is the voltage gain is decibels. |
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*Similarly, we can say current gain in decibels can be found with this equation: <math>\ A_{i dB}=20 log |A_i|</math>, where <math>\ A_i</math> is the current gain and <math>\ A_{i dB}</math> is the current gain is decibels. |
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==Differential Amplifiers== |
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*Differential Amplifiers have two inputs. The terminal marked with a "+" is the noninverting input, and the terminal marked with a "-" is the inverting input. |
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*The differential input signal is given by <math>\ v_{id}=v_{i1}-v_{i2} </math> |
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*The output of an ideal differential amplifier is given by <math>\ v_o=A_d v_{id} </math>. |
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*The common-mode input signal is given by the following: <math>v_{icm}=\frac{1}{2}(v_{i1}+v_{i2})</math>. |
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*A real differential amplifier's output is given by <math>\ v_o=A_d v_{id}+A_{cm} v_{icm} </math>, where <math>A_{cm}</math> is the common-mode signal gain. |
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==References== |
==References== |
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<references/> |
<references/> |
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==Contributors== |
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[[Lau, Chris | Christopher Garrison Lau I]] |
Latest revision as of 13:18, 28 January 2010
The following facts are not profound and are possibly very obvious. Nonetheless, they might help cement certain concepts. Please add things you think would be helpful.
Transistors
- Conduction in n-type material is from free electrons.
- Conduction in p-type material is from holes (positive particles).
- The function of metal-oxide-semiconductor field-effect transistors (MOSFETs) depends on the voltage applied to the gate.
- Certain ranges of voltage allow no current to flow between the drain and the source. In this way, the MOSFET acts like an open switch.
- Another particular range of voltage allows current to easily flow from the source to the drain.
- When the voltage is in between the ranges of open and closed switch, the MOSFET can smoothly control the amount of current flowing.
- Bipolar Junction Transistors (BJTs) can act as either switches or current controls as well.
Amplifiers
- An inverting amplifier has a negative voltage gain, .
- A noninverting amplifier has a positive voltage gain, . (If you get this, you deserve a cookie)
- The power gain,, is the ration of the output power to the input power
-
- is the amplifier's input resistance and is the amplifier's output resistance.
-
Decibel Conversion
- Power gain, , can be converted to decibels:
- By the equation above, we can say voltage gain in decibels can be found with this equation: , where is the voltage gain and is the voltage gain is decibels.
- Similarly, we can say current gain in decibels can be found with this equation: , where is the current gain and is the current gain is decibels.
Differential Amplifiers
- Differential Amplifiers have two inputs. The terminal marked with a "+" is the noninverting input, and the terminal marked with a "-" is the inverting input.
- The differential input signal is given by
- The output of an ideal differential amplifier is given by .
- The common-mode input signal is given by the following: .
- A real differential amplifier's output is given by , where is the common-mode signal gain.
References
<references/>