This study aims at the development of a construction algorithm for brain templates using T1-weighted and diffusion tensor (DT) magnetic resonance imaging (MRI) data. Recently, several brain templates developed in the ICBM-152 stereotactic space, such as ICBM452, ICBM DTI-81 atlas, and IIT DT brain template. In addition to inter-subject variation, however, the brain structures vary with races, genders, ages, and diseases. Hence, a construction algorithm of the stereotactic space for a specific study group can facilitate the structure analysis of the brains. Moreover, we improved the accuracy of registration procedure to reduce the image distortion during the template construction procedure. First, a symmetric and diffeomorphic non-rigid registration algorithm was used to provide both forward and inverse deformation fields. Also, we proposed an objective function which simultaneously utilized both T1-weighted and DT data to improve the accuracy of registration. The DT image is estimated from noise-sensitive diffusion-weighted images (DWIs). All details of DT-MRI processing procedure were carefully considered in this study. First, DT images were estimated from DWIs by the MedINRIA tensor estimation tool, which can tolerate the low signal-to-noise ratio (SNR) in clinical MRI and ensure the positive definiteness of all tensors. For preserving the good property of estimated tensors, Log-Euclidean metrics was used to avoid the problems of the tensor swelling effect and non-positive eigenvalues. In this study, 64 normal subjects were recruited for MRI scanning and template construction. First, we rigidly registered the MRI image to baseline DWI image for each subject to align both modalities of images in the same stereotactic space. Second, a representative subject was chosen as the one having the smallest deformation magnitude when registering to other subject images. Third, each subject image was registered to the temporary template, which was initialized as the image of the representative subject. The average of the obtained inverse deformation fields was applied to the image of the representative subject to update the temporary template. Iteratively applying the third step until the template image converges. Finally, we constructed a representative template and an average template in this converged space. In this study, two criteria were used to evaluate the constructed template images and the registration accuracy, including the DTI differences and overlaps between each subject and the template. The evaluation results showed that the accuracy of non-rigid registration was improved by simultaneously utilizing both T1-weighted and DT data. Furthermore, the results displayed a high correlation between the proposed template and registered subject images. Consequently, the proposed brain template construction could provide a stereotactic space for a specific subject group.