This thesis presents a systematical study of the characteristics of SNRs in the Large Magellanic Cloud (LMC). Due to the known distance and low internal extinction, the LMC provides us great opportunities to study supernova remnants (SNRs). In Part I, we show some interesting groupings in the X-ray luminosity ($L_X$) and size diagram of SNRs: (1) Small LMC SNRs, a few to 10 pc in size, are dominated by Type Ia with $L_X > 10^{36}$ ergs s$^{−1}$. The scarcity of small core-collapse (CC) SNRs is a result of CCSNe exploding in the low-density interiors of interstellar bubbles blown by their massive progenitors. (2) Medium-sized (10-30 pc) CC SNRs show bifurcation in $L_X$, with the X-ray-bright SNRs either in an environment associated with molecular clouds or containing pulsar wind nebulae, and the X-ray-faint SNRs being located in low-density interstellar environments. In Part II, we show that the conventional procedure of identification of Type Ia SNRs is not applicable in galaxies more distant than the Magellanic Clouds, and most Type Ia SNRs are excluded by the criteria of SNR identifications because of their Balmer-dominated line feature. To build up methods to identify young Type Ia, especially Balmer-dominated, SNRs in more distant galaxies, we use the LMC SNR sample to investigate the characteristics of young Type Ia SNRs. We suggest that the $L_X$ in the range $10^{36}-10^{37}$ ergs s$^{−1}$, optical morphology of small round shells, and old stellar and interstellar environments can be treated as the diagnostics to help us identify young Type Ia SNRs. With these characteristics, we establish a new methodology for searching for Type Ia SNRs in the more distant galaxies.