An exact approach is re-visited in performing a comparative analysis of the attractive and repulsive 2-D Hubbard model (AHM and RHM respectively) which is used in describing a simplified 2x1 (Cu-O-Cu) lattice (known to play significant role in HT_c-superconductivity in cuprates) with the use of the MATLAB. The response of the temperature-dependent internal energy, E(kT), to the simultaneous variation of both the on-site interaction and the nearestneighbour hopping integral (U,t) shows that HT_c-superconducting materials described by the AHM are not only more stable but sustain their stable state over a relatively wider temperature range. The spectrum of the magnetic spin susceptibility,x(T), reveal certain interesting character which are used to account for various observed phenomena in HT_c-superconducting materials (like the coexistence of charge density wave (CDW) and spin density wave (SDW) in the semiconducting phase of Ba_1-x K_x BiO₃ and BaPb_x Bi_1-x O₃. Furthermore, various correlations are suggested while the outer limits of the critical values of U for pair formation and associated spin gap, Up=-2eV for AHM and 3eV for RHM. Results obtained are also in strong agreement with results of QMC simulations for more realistic 3-band Hubbard model among others.