Optimising the global detection of solar-like oscillations. Tuning the frequency range for asteroseismic detection predictions and searches

TL;DR

This paper refines the method for predicting solar-like oscillation detectability by identifying an optimal frequency range, improving detection success rates and yield predictions for asteroseismic surveys.

Contribution

It demonstrates that using a frequency range width of approximately 1.2 times the envelope width maximizes detection probability, challenging the previously assumed factor of 2.

Findings

Optimal frequency range width is about 1.2 times the envelope width.

Using the new factor improves detection probability and yield predictions.

The choice of frequency range significantly impacts detection success.

Abstract

A well-established method exists for predicting the detectability of solar-like oscillations and has been widely used to support target selection for space-based photometric missions. The method evaluates the probability of an asteroseismic detection from the expected global signal-to-noise ratio (SNR) of the oscillation signal relative to the broadband background from shot noise and granulation. Stellar parameters are used to estimate the oscillation and granulation signals, while instrumental properties and apparent stellar brightness determine the expected shot noise. We investigate whether there is an optimal choice for the frequency range, $W$, over which the global SNR is calculated. The oscillation power is assumed to follow a Gaussian-like envelope with full width at half maximum $\Gamma_{\rm env}$ centred on the frequency of maximum oscillation power. It has commonly been assumed that $W \simeq 2\Gamma_{\rm env}$ when predicting detections. We compute numerical predictions of the global SNR and corresponding detection probabilities for a range of stellar and observational parameters, adopting widths $W=\alpha\Gamma_{\rm env}$ where $\alpha$ is a multiplicative factor. We also examine the impact of this choice on detection yields across a population of targets using bright solar-like oscillators observed by TESS as a representative sample. We find that the commonly adopted value $\alpha \simeq 2$ is suboptimal and that $\alpha \simeq 1.2$ maximises the detection probability. This choice can also significantly affect predicted detection yields for stellar samples. We therefore recommend adopting $W \simeq 1.2\Gamma_{\rm env}$ both when computing detection probabilities and when searching for oscillations in real data via tests of excess mode power, as it optimises the probability of robust detections.