Research data supporting "A machine learning approach to drawing phase diagrams of topological lasing modes"

To classify the topological states of lasing modes, one needs to solve rate equations and then can analyze the time-dependent data using different machine learning approaches: 1) fixed library, 2) top-down adaptive library, and 3) bottom-up datative library. In this paper, we consider a coupled resonator arrays, so called SSH lattice, with 21 sites. To build libraries, we used 2000 samples implying we considered 2000 different set of gain and linear loss coefficients that forms a 2D parameter space presented in the paper. In this paper, all the coefficients are normalised so that no units are required when solving the equations and presenting the results.  First, the data file "dataset_params.txt"  contains the parameters used for the time evolution of the system, and the initial conditions, for each samples generated. It contains 24 columns where the first three columns are the sample index, gain (g_A) and linar loss coefficients (g_AB) for A sites and A and B sites, respectively. Note that we have 2000 samples that is equal to the number of points in graphs in the paper and the sample index was not sorted in ascending/desceding order because the order is not important. The remaining 21 columns are the intial values of site amplitude, x(t=0), that were used when solving the rate equations Eq. (2) and Eq. (3) using the 4th-order Runge-Kutta method. Here, we used 0.01 commonly for all the sites (N=21) and all the different samples (2000). Second, the data file "dataset_time_series.txt"  contains time evolution of the system for each samples generated. The first  column is the sample index, the remaining 42 columns are  the complex amplitudes of the mode corresponding to Re(a(x=1,t=t0)), Im(a(x=1,t0)), Re(a(x=2,t=t0)), Im(a(x=2,t=t0)), ...., Re(a(x=1,t=t1)), ... . Third, there are 8 data files that correspond to phase diagrams calculated using the methods describe in the manuscript. All of them have the same structure and contains derived phase diagram, i.e., the first and second columns are the linear loss coefficeints (g_AB) and the gain coefficient (g_A) and the third column is the index for different phases.  filenames:     ahdmd?tab_class_ij.txt     ahdmd?tab_class_ij_bis2.txt     xc_tab_class_red_i_5.txt     xc_tab_class_red_i_1.txt     xc_tab_class_red_i_-2.txt     xc_tab_class_red_ij_0_3.txt     xc_tab_class_red_ij_0_7.txt     xc_tab_class_red_ij_3_7.txt The datafiles are used in figures as described below ===================== Files used in figures ===================== Figure 1: dataset_params.txt dataset_time_series.txt  Figure 2: panel a: ahdmd?tab_class_ij.txt panel b: ahdmd?tab_class_ij_bis2.txt Figure 3: xc_tab_class_red_i_5.txt Figure 4: panel a: method is applied for each hyper-parameter value on times series in dataset_time_series, then the number of classes is counted panel b: xc_tab_class_red_i_1.txt panel c: xc_tab_class_red_i_-2.txt Figure 5: xc_tab_class_red_ij_0_3.txt Figure 6: panel a: method is applied for each hyper-parameter value on times series in dataset_time_series, then the number of classes is counted panel b: xc_tab_class_red_ij_0_7.txt panel c: xc_tab_class_red_ij_3_7.txt Figure S1-S3: use sample in dataset_time_series.txt corresponding to parameters gamma_AB, g_a of panel d-e of figure 1 Figure S4: Apply described method on each decomposition methods on times series in dataset_time_series.txt Figure S5: Apply described method on times series in dataset_time_series.txt Figure S6: Apply described method on times series in dataset_time_series.txt Research results based upon these data are published at https://doi.org/10.1038/s42005-023-01230-z