The damping parameter ${alpha}_{text{FM}}$ in ferrimagnets defined by following the conventional practice for ferromagnets is known to be strongly temperature dependent and diverge at the angular momentum compensation temperature, where the net angular momentum vanishes. However, recent theoretical and experimental developments suggest that the damping parameter can be defined in such a way, which we denote by ${alpha}_{text{FiM}}$, that it is free of the diverging anomaly at the angular momentum compensation point and is little dependent of temperature. To further understand the temperature dependence of the damping parameter in ferrimagnets, we analyze several data sets from literature for gadolinium iron garnet (Gd$_3$Fe$_5$O$_{12}$) by using the two different definitions of the damping parameter. Using two methods to estimate the individual sublattice magnetizations, which yield results consistent with each other, we found that in all the used data sets, the damping parameter ${alpha}_{text{FiM}}$ does not increase at the angular compensation temperature and shows no anomaly whereas the conventionally defined ${alpha}_{text{FM}}$ is strongly dependent on the temperature.