I've been asked to present a possible solution to design an optical system aimed at estimating the arrival time of the following light signal:
$$s(t)=[\Sigma_{i=1}^∞rect(\frac{t-t_i}{T})]\cdot Acos(ω_0 t+φ)$$
with:
- ω0=2π∙50MHz
- T=100us
- t(i+1)-ti=200us
- Pin=-30dBm
Requirements for the amplifier:
- Use a photodiode
- 20Ω input impedance
- 50Ω output impedance
- Responsivity 0.8 A/W;
- Minimum output voltage 100mVpp
- Sufficient bandwidth for the input signal
What I am asking you
I do not want to ask you to do my homework. But I do not know how to start since I have lots of doubts. So, I'm asking to get some clarifications and suggestions that will help me proceed. I'll put here what I'll get with your advice. Precisely:
1. A responsivity of 0.8 A/W is required. Is it only a property of the photodiode or does it depend also on the surrounding circuitry? If I choose a photodiode with such a responsivity, can I say this requirement is filled?
2. I've sketched the behaviour of the incident light signal:
Can I assume the photodiode to be linear so that the current it generates has the same behaviour?
3. About the bandwidth , I have done the following thinking. The spectrum of a rect is a sinc, and the spectrum of a train of rects is a sampled sinc. The latter will be shifted at ω0=2π∙50MHz. The main lobe of a sinc is large 1/(rect duration) = 1/T = 10kHz. Hence, if we decide to let the main lobe pass, we need an amplifier which works from 40MHz to 60MHz. Do you agree with me?
4. What might be a reason for asking a 20Ω input impedance? Is it just a casual homework requirement? As the photodiode behaves like a real current source, wouldn't be better if it were connected to a 0Ω load?
5. What is the simplest circuital topology you know which has the degrees of freedom for the requirements?
The simplest I know is this one:
But I would have to add a 20Ω series resistance at input and a 50Ω parallel resistance at output to fill the requirements. That does not seem to me a good idea.
Can you suggest a topology which lets me fill those requirements? The simpler the topology (also by neglecting some parasitic behaviours) the better it is since I'm newbie on this topic.
6. Does the amplifier have to be necessarily bandpass between 40 and 60MHz, or can it be also a low pass filter (from 0 to 60MHz) or high pass filter (from 40MHz) to keep the initial signal shape?
Best Answer
OTA’s are used to amplify current sources and the feedback R is the input resistance. The output resistance rises to the open loop Rs of any negative feedback amplifier as the gain reduces to u it’s at max GBW product thus a 50 ohm driver is a special consideration for video amps with high gain at 50 MHz and largely determined by the collector R.
As you may have already guessed -30 dBm is 1uW optical and so 0.8uA/uW into 20 Ohms is only 16uV so you need a large voltage gain with a 50 Ohm output impedance after the OTA to get your required output voltage. RC =T feedback must match RC=T of the PD for a flat response up to the GBW product (-3dB) of the OTA IC.
Parasitics of the geometric pF are also important in the layout.
That should get you started. If you get stuck , I’m sure you can find an answer with a schematic on the web, but only if you get stuck ;). You might be expected to design this with discrete FETS but you will need more than 50MHz BW.