Noise spectra in balanced optical detectors based on transimpedance amplifiers

TL;DR

This paper provides a comprehensive theoretical and experimental analysis of shot and electronic noise spectra in balanced optical detectors using transimpedance amplifiers, highlighting key parameters affecting performance.

Contribution

It offers new insights into the noise behavior and identifies discrepancies in amplifier input capacitance measurements compared to datasheet specifications.

Findings

Shot noise spectrum aligns with second order Butterworth filter

Electronic noise increases linearly with the square of frequency

Input capacitances are higher than datasheet values

Abstract

We present a thorough theoretical analysis and experimental study of the shot and electronic noise spectra of a balanced optical detector based on an operational amplifier (OA) connected in a transimpedance scheme. We identify and quantify the primary parameters responsible for the limitations of the circuit, in particular the bandwidth and shot-to-electronic noise clearance. We find that the shot noise spectrum can be made consistent with the second order Butterworth filter, while the electronic noise grows linearly with the second power of the frequency. Good agreement between the theory and experiment is observed, however the capacitances of the operational amplifier input and the photodiodes appear significantly higher than those specified in manufacturers' datasheets. This observation is confirmed by independent tests.