Optimising the directional sensitivity of LISA

TL;DR

This paper demonstrates how to optimize LISA's sensitivity for known-direction monochromatic sources by using tailored data combinations, significantly improving SNR and enabling parameter estimation.

Contribution

It introduces a method to coherently track sources by switching data combinations, enhancing LISA's sensitivity beyond standard approaches.

Findings

SNR improvement up to 90% at 20 mHz for sources in the ecliptic plane

LISA can be treated as two independent detectors with the network statistic

Inclination angle can be estimated if both polarizations are measured at low frequencies

Abstract

It was shown in a previous work that the data combinations canceling laser frequency noise constitute a module - the module of syzygies. The cancellation of laser frequency noise is crucial for obtaining the requisite sensitivity for LISA. In this work we show how the sensitivity of LISA can be optimised for a monochromatic source - a compact binary - whose direction is known, by using appropriate data combinations in the module. A stationary source in the barycentric frame appears to move in the LISA frame and our strategy consists of "coherently tracking" the source by appropriately "switching" the data combinations so that they remain optimal at all times. Assuming that the polarisation of the source is not known, we average the signal over the polarisations. We find that the best statistic is the `network' statistic, in which case LISA can be construed of as two independent detectors. We compare our results with the Michelson combination, which has been used for obtaining the standard sensitivity curve for LISA, and with the observable obtained by optimally switching the three Michelson combinations. We find that for sources lying in the ecliptic plane the improvement in SNR increases from 34% at low frequencies to nearly 90% at around 20 mHz. Finally we present the signal-to-noise ratios for some known binaries in our galaxy. We also show that, if at low frequencies SNRs of both polarisations can be measured, the inclination angle of the plane of the orbit of the binary can be estimated.