Chapter 1: Difference between revisions

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==Amplifier Models==
'''Chapter 1'''
*These are purely models, and cannot be replicated in a real world environment. They are meant to explain.
*Amplifier Models
*Trans stands for transfer (from voltage to current or visa versa).
:*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).
:*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)



:{| class="wikitable" border="1"
{| class="wikitable" border="1"
! Amplifier type <br> Gain type
|+ Amplifier models
! Amplifier type <br> Gain parameter<br> Gain equation
! Voltage input
! Voltage input
! Current input
! Current input
|- align="center"
|- align="center"
! Voltage output
! Voltage output
| Voltage <br> <math>A_{vo}</math>, Open-circuit voltage gain
| Voltage <br> Open-circuit voltage gain <br> <math>A_{voc}=\frac{v_{ooc}}{v_i}</math>
| Transresistance <br> <math>R_{moc}</math>, Open-circuit transresistance gain
| Transresistance <br> Open-circuit transresistance gain <br> <math>R_{moc}=\frac{v_{ooc}}{i_i}</math>
|- align="center"
|- align="center"
! Current output
! Current output
| Transconductance <br> <math>G_{msc}</math>, Short-circuit transconductance gain
| Transconductance <br> Short-circuit transconductance gain <br> <math>G_{msc}=\frac{i_{osc}}{v_i}</math>
| Current <br> <math>A_{isc}</math>, Short-circuit current gain
| Current <br> Short-circuit current gain <br> <math>A_{isc}=\frac{i_{osc}}{i_i}</math>
|}
|}


#Voltage
##To find the voltage-amplifier model for an amplifier, we must determine the open-circuit voltage gain, the input impedance, and the output impedance
#Current
##"As before, the input resistance accounts for the current that the amplifier draws from the signal source. The output resistance is now in parallel with the controlled source and accounts for the fact that the amplifier cannot supply a fixed current to an arbitrarily high load resistance."
##To find the current amplifier model, we must determine the short-circuit current gain, the input impedance, and the output impedance
#Transconuductance
#Transresistance


{| class="wikitable" border="1"
*Definitions - ripped straight from the book
|+ Characteristics of ideal amplifiers
**Input Resistance: <math>R_i</math> of an amplifier is the equivalent resistance seen when looking into the input terminals
! Amplifier <br> Type !! Input <br> Impedance !! Output <br> Impedance !! Gain <br> Parameter
**Output Resistance:<math>R_o</math> is the Thevenin resistance seen when looking back into the output terminals of an amplifier
|-align="center"
**Open-circuit voltage gain: the ratio of output amplitude to input amplitude with the output terminals open circuited
! Voltage
**Short-circuit current gain: the current gain with the output terminals of the amplifier short circuited
| <math>\infty</math>
| 0
| <math>A_{voc}\,</math>
|-align="center"
! Current
| 0
| <math>\infty</math>
| <math>A_{isc}\,</math>
|-align="center"
! Transconductance
| <math>\infty</math>
| <math>\infty</math>
| <math>G_{msc}\,</math>
|-align="center"
! Transresistance
| 0
| 0
| <math>R_{moc}\,</math>
|}

==Differential Amplifiers==
[[Image:Differential Amplifier.PNG|thumb|300px| Differential Amplifier inputs]]
*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 <math>v_{1}\,</math> and <math>v_{i}\,</math>, we can express them in terms of the differential and common-mode input.
**Differential input signal is the difference between the input voltages. <math>v_{d}=v_{1}-v_{2}\,</math>
**Common-mode input signal is the average of the input voltages. <math>v_{cm}=\frac{1}{2}(v_{1}+v_{2})</math>
**<math>v_{1}=v_{cm}+\frac{v_{d}}{2}</math>, if <math>v_{1}\,</math> is voltage at the positive terminal.
**<math>v_{2}=v_{cm}-\frac{v_{d}}{2}</math>, if <math>v_{2}\,</math> is voltage at the negative terminal.
*<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.
*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, <math> CMRR = 20 \log \frac{| A_d |}{| A_{cm}|}</math>

==Definitions==
*Input Resistance: <math>R_i</math> of an amplifier is the equivalent resistance seen when looking into the input terminals.
*Output Resistance: <math>R_o</math> 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.

==Capacitor==
:<math>v(t)= \frac{q(t)}{C} = \frac{1}{C}\int_{t_0}^t i(\tau) \mathrm{d}\tau+v(t_0)</math>
:<math>i(t)= \frac{\mathrm{d}q(t)}{\mathrm{d}t}=C\frac{\mathrm{d}v(t)}{\mathrm{d}t}</math>
==Inductor==
:<math>v(t) = L \frac{di(t)}{dt}</math>
:<math>i(t) = \frac{1}{L} \int^t_{t_0} v(\tau)d\tau + i({t_0})</math>

==Reviewers==
*[[Lau, Chris | Christopher Garrison Lau I]]
*[[Vier, Michael | Michael Vier]]

==Readers==


*[[Lau, Chris | Christopher Garrison Lau I]]
*Bag of Tricks
**Buffer amplifier
**Inverting amplifier

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 models
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


Characteristics of ideal amplifiers
Amplifier
Type
Input
Impedance
Output
Impedance
Gain
Parameter
Voltage 0
Current 0
Transconductance
Transresistance 0 0

Differential Amplifiers

Differential Amplifier inputs
  • 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.

Capacitor

Inductor

Reviewers

Readers