Chapter 1: Difference between revisions
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(New page: '''Chapter 1''' *Amplifier Models **These are purely models, and cannot be replicated in a real world environment. They are meant to explain. **Trans stands for transfer - from voltage to ...) |
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'''Chapter 1''' |
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*Trans stands for transfer (from voltage to current or visa versa). |
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*The inputs and outputs can be either current or voltage. This leads to 4 amplifier models. |
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*You can use any of these models, though some may be easier to work with (if you are given the Thevenin or Norton equivalent). |
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**The inputs and outputs can be either current or voltage. This leads to 4 amplifier models. |
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{| class="wikitable" border="1" |
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#Transconuductance |
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|+ Amplifier models |
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! Amplifier type <br> Gain parameter<br> Gain equation |
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! Voltage input |
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! Current input |
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|- align="center" |
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! Voltage output |
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| Voltage <br> Open-circuit voltage gain <br> <math>A_{voc}=\frac{v_{ooc}}{v_i}</math> |
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| Transresistance <br> Open-circuit transresistance gain <br> <math>R_{moc}=\frac{v_{ooc}}{i_i}</math> |
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|- align="center" |
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! Current output |
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| Transconductance <br> Short-circuit transconductance gain <br> <math>G_{msc}=\frac{i_{osc}}{v_i}</math> |
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| Current <br> Short-circuit current gain <br> <math>A_{isc}=\frac{i_{osc}}{i_i}</math> |
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|} |
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{| class="wikitable" border="1" |
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|+ Characteristics of ideal amplifiers |
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! Amplifier <br> Type !! Input <br> Impedance !! Output <br> Impedance !! Gain <br> Parameter |
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| <math>\infty</math> |
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| 0 |
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| <math>A_{voc}\,</math> |
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| 0 |
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| <math>\infty</math> |
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| <math>A_{isc}\,</math> |
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|-align="center" |
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! Transconductance |
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| <math>\infty</math> |
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| <math>\infty</math> |
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| <math>G_{msc}\,</math> |
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| 0 |
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| 0 |
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| <math>R_{moc}\,</math> |
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|} |
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==Differential Amplifiers== |
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[[Image:Differential Amplifier.PNG|thumb|300px| Differential Amplifier inputs]] |
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*Differential amplifiers take two (or more) input sources and produce an output voltage proportional to the difference between the input voltages. |
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*Instead of expressing the input voltages in terms of <math>v_{1}\,</math> and <math>v_{i}\,</math>, we can express them in terms of the differential and common-mode input. |
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**Differential input signal is the difference between the input voltages. <math>v_{d}=v_{1}-v_{2}\,</math> |
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**Common-mode input signal is the average of the input voltages. <math>v_{cm}=\frac{1}{2}(v_{1}+v_{2})</math> |
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**<math>v_{1}=v_{cm}+\frac{v_{d}}{2}</math>, if <math>v_{1}\,</math> is voltage at the positive terminal. |
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**<math>v_{2}=v_{cm}-\frac{v_{d}}{2}</math>, if <math>v_{2}\,</math> is voltage at the negative terminal. |
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*<math>v_o=A_d v_{d} + A_{cm} v_{cm}\,</math>, where <math>A_d\,</math> is the differential gain and <math>A_{cm}\,</math> is the common mode gain. |
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*The common-mode rejection ratio (CMRR) is the ratio of the magnitude of the differential gain to the magnitude of the common-mode gain. |
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**In decibels, <math> CMRR = 20 \log \frac{| A_d |}{| A_{cm}|}</math> |
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==Definitions== |
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*Input Resistance: <math>R_i</math> of an amplifier is the equivalent resistance seen when looking into the input terminals. |
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*Output Resistance: <math>R_o</math> is the Thevenin resistance seen when looking back into the output terminals of an amplifier. |
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*Open-circuit voltage gain: the ratio of output amplitude to input amplitude with the output terminals open circuited. |
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*Short-circuit current gain: the current gain with the output terminals of the amplifier short circuited. |
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==Capacitor== |
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:<math>v(t)= \frac{q(t)}{C} = \frac{1}{C}\int_{t_0}^t i(\tau) \mathrm{d}\tau+v(t_0)</math> |
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:<math>i(t)= \frac{\mathrm{d}q(t)}{\mathrm{d}t}=C\frac{\mathrm{d}v(t)}{\mathrm{d}t}</math> |
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==Inductor== |
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:<math>v(t) = L \frac{di(t)}{dt}</math> |
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:<math>i(t) = \frac{1}{L} \int^t_{t_0} v(\tau)d\tau + i({t_0})</math> |
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==Reviewers== |
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*[[Lau, Chris | Christopher Garrison Lau I]] |
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*[[Vier, Michael | Michael Vier]] |
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==Readers== |
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*[[Lau, Chris | Christopher Garrison Lau I]] |
Latest revision as of 13:50, 11 March 2010
Amplifier Models
- These are purely models, and cannot be replicated in a real world environment. They are meant to explain.
- Trans stands for transfer (from voltage to current or visa versa).
- The inputs and outputs can be either current or voltage. This leads to 4 amplifier models.
- You can use any of these models, though some may be easier to work with (if you are given the Thevenin or Norton equivalent).
Amplifier type Gain parameter Gain equation |
Voltage input | Current input |
---|---|---|
Voltage output | Voltage Open-circuit voltage gain |
Transresistance Open-circuit transresistance gain |
Current output | Transconductance Short-circuit transconductance gain |
Current Short-circuit current gain |
Amplifier Type |
Input Impedance |
Output Impedance |
Gain Parameter |
---|---|---|---|
Voltage | 0 | ||
Current | 0 | ||
Transconductance | |||
Transresistance | 0 | 0 |
Differential Amplifiers
- Differential amplifiers take two (or more) input sources and produce an output voltage proportional to the difference between the input voltages.
- Instead of expressing the input voltages in terms of and , we can express them in terms of the differential and common-mode input.
- Differential input signal is the difference between the input voltages.
- Common-mode input signal is the average of the input voltages.
- , if is voltage at the positive terminal.
- , if is voltage at the negative terminal.
- , where is the differential gain and is the common mode gain.
- The common-mode rejection ratio (CMRR) is the ratio of the magnitude of the differential gain to the magnitude of the common-mode gain.
- In decibels,
Definitions
- Input Resistance: of an amplifier is the equivalent resistance seen when looking into the input terminals.
- Output Resistance: is the Thevenin resistance seen when looking back into the output terminals of an amplifier.
- Open-circuit voltage gain: the ratio of output amplitude to input amplitude with the output terminals open circuited.
- Short-circuit current gain: the current gain with the output terminals of the amplifier short circuited.