LitePIG: a lite parameter inference system for the gravitational wave in the millihertz band

LitePIG: a lite parameter inference system for the gravitational wave in the millihertz band

Abstract We present a Python based parameter inference system for the gravitational wave (GW) measured in the millihertz band. This system includes the following features: the GW waveform originated from the massive black hole binaries (MBHB), the stationary instrumental Gaussian noise, the higher-o...

Full description

Saved in:
Bibliographic Details
Published in:Communications in theoretical physics 2023-07, Vol.75 (7), p.75402
Main Authors: Wang, Renjie, Hu, Bin
Format: Article
Language:eng
Subjects:
data analysis
gravitational wave astronomy
parameter estimation
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Abstract We present a Python based parameter inference system for the gravitational wave (GW) measured in the millihertz band. This system includes the following features: the GW waveform originated from the massive black hole binaries (MBHB), the stationary instrumental Gaussian noise, the higher-order harmonic modes, the full response function from the time delay interferometry and the Gaussian likelihood function with the dynamic nested parameter sampler. In particular, we highlight the role of higher-order modes. By including these modes, the luminosity distance estimation precision can be improved roughly by a factor of 50, compared with the case with only the leading order ( ℓ = 2, ∣ m ∣ = 2) mode. This is due to the response functions of different harmonic modes on the inclination angle are different. Hence, it can help to break the distance-inclination degeneracy. Furthermore, we show the robustness of testing general relativity (GR) by using higher-order harmonics. Our results show that the GW from MBHB can simultaneously constrain four of the higher harmonic amplitudes (deviation from GR) with 95% confidence level of c 21 = 0.54 − 1.05 + 0.82 , c 32 = − 0.65 − 1.42 + 3.02 , c 33 = 0.56 − 0.96 + 0.79 and c 44 = 1.57 − 2.19 + 3.22 , respectively.
ISSN:0253-6102
1572-9494