Dies ist eine alte Version des Dokuments!
Excercise 3.5.2. Variations of the non-inverting amplifier
Below you will find circuits with an ideal operational amplifier, which are similar to the non-inverting amplifier and whose voltage gain $A_V$ must be determined.
Assumptions
- $R_1 = R_3 = R_4 = R$
- $R_2 = 2 \cdot R$
- $U_I$ comes from a low-resistance source
- $U_O$ is due to a high-resistance consumer
Exercises
- Enter the voltage gain $A_V$ for each circuit. A detailed calculation as before is not necessary.
- For Figure 7, indicate how the voltage gain can be determined.
- Generalize with justification how
- a short circuit of the two OPV inputs must be taken into account,
- Resistances are to be considered when doing this:
- with a terminal („on one side“) are directly and exclusively on an OPV input,
- with one terminal each are directly connected to an OPV input.
- In which circuits do resistors $R_3$ and $R_4$ represent an unloaded voltage divider?
In order to approach the problems, you should try to use the knowledge from the inverting amplifier. It can be useful to simulate the circuits via Falstad-Circuit or Tina TI. In the first two circuits, tips can be seen under the illustration as support.
Important : As always in your studies, you should try to generalize the knowledge gained from the task.
Tipps
- How big is the current flow into the inverting and non-inverting input of an ideal operational amplifier? So what voltage drop would there be across a resistor whose one connection only leads to one input of the operational amplifier ($R_3$)?
- The operational amplifier always tries to output as much current at the output that the required minimum voltage $U_D$ results between the inverting and non-inverting input. How high can $U_D$ be assumed? Can this voltage also be built up via a resistor ($R_4$)?
- Can different resistors (e.g. because they are between the same nodes) be combined?
Abb. 1
Abb. 2
Abb. 3
Abb. 4
Abb. 5
Abb. 6
Abb. 7
Abb. 8
Abb. 9
