Ultra-wide frequency response measurement of an optical system with a DC photo-detector

TL;DR

This paper introduces a novel calibration method for measuring the frequency response of optical systems using a low-frequency photo-detector, eliminating bandwidth limitations and calibration requirements of traditional techniques.

Contribution

A new calibration technique that uses a DC photo-detector to measure optical system frequency response without bandwidth constraints or prior calibration.

Findings

Successfully measured cavity resonant frequencies with high precision.

Demonstrated repeatability in characterizing orthogonal polarization modes.

Applicable to passive optical elements after initial calibration.

Abstract

Precise knowledge of an optical device's frequency response is crucial for it to be useful in most applications. Traditional methods for determining the frequency response of an optical system (e.g. optical cavity or waveguide modulator) usually rely on calibrated broadband photo-detectors or complicated RF mixdown operations. As the bandwidths of these devices continue to increase, there is a growing need for a characterization method that does not have bandwidth limitations, or require a previously calibrated device. We demonstrate a new calibration technique on an optical system (consisting of an optical cavity and a high-speed waveguide modulator) that is free from limitations imposed by detector bandwidth, and does not require a calibrated photo-detector or modulator. We use a low-frequency (DC) photo-detector to monitor the cavity's optical response as a function of modulation frequency, which is also used to determine the modulator's frequency response. Knowledge of the frequency-dependent modulation depth allows us to more precisely determine the cavity's characteristics (free spectral range and linewidth). The precision and repeatability of our technique is demonstrated by measuring the different resonant frequencies of orthogonal polarization cavity modes caused by the presence of a non-linear crystal. Once the modulator has been characterized using this simple method, the frequency response of any passive optical element can be determined.