Study of petal shape variation is necessary for exploring petal morphology. Petals are complex in structures and vary tremendously. To describe petal shape accurately, three-dimensional (3D) methods were applied to this study. This study aimed to acquire 3D images using microcomputed tomography (μCT). 3D geometric morphometrics (GM) methods were used to evaluate major petal shape variations. The petal traits were physically identified according to the principal shape variations. The second generation (F2) populations of Sinningia speciosa (S. speciosa) resulting from intercross between a zygomorphic variety and an actinomorphic cultivar were applied to this study. The petal shapes of F2 population in S. speciosa were found largely associated with genotypic combinations of CYCLOIDEA (SsCYC) genotypes. The genotype-phenotype association was investigate to realize whether SsCYC genotypes played a key role in controlling the petal traits. The actinomorphic plants in S. speciosa developed flowers in which dorsal petals resembled the ventral petals. Venrtralization of the dorsal petals on actinomorphic plants was then examined morphologically by measuring the degree of shape similarity using Hausdorff distance. The 3D-GM methods approximately identified the petal shapes variations and defined the petal traits. Numerous petal traits, including petal width and left-right asymmetry of the dorsal petals, recurvation and petal size of the lateral petals, recurvation and lobe size of the ventral petals were identified not associated with SsCYC genotypes. The shape similarity analysis indicated that actinomorphic plants have ventralized phenotypes.