My circuit is given below.
I used this equation for calculating the bandwidth of the TIA.
My RF is 200 kΩ and Cd is 1.3 pF (diode) + 9 pF (opamp input capacitance).
After calculation I am getting a value of 11 MHz and simulated value is 800Khz;.
May I know why such a difference?
EDIT:1
As Andy and Vincent suggested I removed the feedback capacitor and re run my simulation.Please see the response below.May I know is this expected.
C1 and RF created a low-pass filter.
$$ \frac{1}{2.\pi .200k.1pF}=795\:774Hz$$
Try removing C1 from the simulation.
- Edited following clarification of the OP's question -
Here are the results I obtained in a simulation with C1. The gain is 106.02dB, which corresponds to a current/voltage conversion of 200,000 and a cutoff frequency of 800kHz.
Without C1, the cutoff frequency is 11.32MHz.
Curve GAIN_I_to_V = VOUT/AM1
- Edited following a question from the OP in comments -
If you look at the ROC (Rate Of Closure), the cross between the open-loop gain and the noise gain of your OPA301, you'll see that the presence of Cf reduces the ROC = 20dB = stable system.
Ressources: https://www.youtube.com/watch?v=U6tP78BLr_A https://www.ti.com/video/6216778063001
After calculation I am getting a value of 11 MHz and simulated value is 800Khz
The formula that you have used is being totally overridden by the feedback capacitor. It with the feedback resistor are the dominant components that define the banwidth: -
$$BW = \dfrac{1}{2\pi R_F C_F}$$
