Adaptive evolution of vision-related genes has been frequently observed in the process of invasion of new environments in a wide range of animal taxa. The typical example is that of the molecular evolution of rhodopsin associated with habitat changes in aquatic animals. However, few studies have investigated rhodopsin evolution during adaptive radiation across various habitats. In the present study, we examined the link between molecular evolutionary patterns in the rhodopsin gene and macroscopic habitat changes in Gymnogobius species (Gobiidae), which have adaptively radiated to diverse aquatic habitats including the sea, brackish waters, rivers and lakes. Analysis of amino acid substitutions in rhodopsin in the phylogenetic framework revealed convergent substitutions in 4–5 amino acids in three groups (four species), including two spectral tuning amino acid sites known to change rhodopsin’s absorption wavelength. Positive selection was detected in the basal branches of each of these three groups, suggesting adaptive molecular convergence of rhodopsin. However, no significant correlation was observed between amino acid substitutions and the species’ habitat changes, suggesting molecular adaptation to some unidentified micro-ecological environments. Taken together, these results emphasise the importance of considering not only macroscopic habitats but also micro-ecological environments when elucidating the driving forces of adaptive evolution of the visual system.