Investigating scaling relations in X-ray reverberating AGN using symbolic regression

Symbolic regression (SR) is a regression analysis based on genetic algorithms to search for mathematical expressions that best fit a given data set, by allowing the expressions themselves to mutate. We use the SR to analyse the parameter relations of the X-ray reverberating active galactic nuclei where the soft Fe-L lags were observed by the X-ray Multi-Mirror Mission (XMM-Newton). First, we revisit the lag-mass scaling relations by using the SR to derive all possible mathematical expressions and test them in terms of accuracy, simplicity, and robustness. We find that the correlation between the lags, tau, and the black hole mass, M-BH, is certain, but the relation should be written in the form of log(tau) = alpha + beta(log(M-BH/M-circle dot))(gamma), where 1 less than or similar to gamma less than or similar to 2. Moreover, incorporating more parameters such as the reflection fraction (RF) and the Eddington ratio (lambda(Edd)) to the lag-mass scaling relation is made possible by the SR. It reveals that alpha, rather than being a constant, can be -2.15 + 0.02RF or 0.03(RF + lambda(Edd)), with the fine-tuned different beta and gamma. These further support the relativistic disc-reflection framework in which such functional dependences can be straightforwardly explained. Furthermore, we derive their host-galaxy mass, M-*, by fitting the spectral energy distribution. We find that the SR model supports a non-linear M-BH-M-* relationship, while log(M-BH/M-*) varies between -5.4 and -1.5, with an average value of similar to-3.7. No significant correlation between M-* and lambda(Edd) is confirmed in these samples.