Simultaneously search for multi-target Galactic binary gravitational waves in reduced parameter space with LMPSO-CV

We propose an innovative approach to the concurrent exploration of gravitational waves originating from Galactic binaries through the development of a new Local Maxima Particle Swarm Optimization (LMPSO) algorithm. Our methodology employs strategic Create Voids (CV) to streamline parameter space, maximizing the identification of local maxima for the $\mathcal{F}$-statistic even in the overlapped signals case. Subsequently, a "find-real-$\mathcal{F}$-statistic-analysis", which implements the astrophysical models and properties of $\mathcal{F}$-statistic in parameter space, is conducted to reveal Galactic binary gravitational wave signals within the dataset. Our new approach eliminates inaccuracies associated with signal subtraction contamination, which is a challenge for traditional iterative-subtraction method when addressing low signal-to-noise ratio signals (e.g., SNR $<$ 15). We also consider the effect of overlapping signals and degeneracy noise. To demonstrate the efficacy of our approach, we utilize the residuals from the LISA mock data challenge (LDC1-4), where 10982 injection sources with SNR $\ge$ 15 have been eliminated. For the remaining low SNR sources (SNR $<$ 15), the LMPSO-CV method efficiently identifies 8995 signals with a 52.3\% detection rate or 3463 signals with a 73.1\% detection rate when the correlation coefficient threshold $R_t$ is set to 0.8.