Chapter 2: Difference between revisions
Jump to navigation
Jump to search
(New page: =Ideal Op Amp Characteristics= *Infinite input impedance *Infinite open-loop gain for the differential signal *Zero gain for the common mode signal *Zero output impedance *Infinite bandwid...) |
|||
| Line 1: | Line 1: | ||
=Ideal Op Amp Characteristics= |
=Ideal Op Amp Characteristics= |
||
*Infinite input impedance |
*[[Chapter_1#Amplifier_Models | Infinite input impedance]] |
||
*Infinite open-loop gain for the differential signal |
*Infinite open-loop gain for the differential signal |
||
*Zero gain for the common mode signal |
*Zero gain for the common mode signal |
||
**You can easily change an differential amplifier into a common-mode amplifier by grounding one of the inputs |
|||
*Zero output impedance |
|||
*[[Chapter_1#Amplifier_Models | Zero output impedance]] |
|||
*Infinite bandwidth |
*Infinite bandwidth |
||
**To allow for infinite gain regardless of the frequency? |
|||
=Op Amp Nodal Analysis= |
=Op Amp Nodal Analysis= |
||
*No current flows into the + or - terminals |
*No current flows into the + or - terminals |
||
Revision as of 12:25, 11 January 2010
Ideal Op Amp Characteristics
- Infinite input impedance
- Infinite open-loop gain for the differential signal
- Zero gain for the common mode signal
- You can easily change an differential amplifier into a common-mode amplifier by grounding one of the inputs
- Zero output impedance
- Infinite bandwidth
- To allow for infinite gain regardless of the frequency?
Op Amp Nodal Analysis
- No current flows into the + or - terminals
- If negative feedback is present (and no positive feedback), then
- Write nodal equations at and , but not at
