The near-infrared light is weakly absorbed between 600-900 nm in the human tissue. Therefore, the optical imaging system with the deep penetration characteristic can be applied to biomedical instrument. Diffuse optical tomography (DOT) is an emerging technique for biomedical imaging based on the near-infrared photons. It is a technique that images spatial variations in absorption and scattering properties of the biological tissues. For the clinical studies, the breast cancer detection, the functional brain imaging, and the diagnosis of exercise medicine will be concerned and focused in further research. It has the advantages of noninvasive, real-time, non-radiation and functional imaging. Generally, the categories of DOT development are divided into two parts: one is the devices choice of light source and photo-detector and the other is the image reconstruction algorithm. The image quality of DOT technique strongly depends on the reconstruction algorithm. In this thesis, inhomogeneities with various shapes of absorption distributions in turbid media are simulated. The DOT images are reconstructed based on the simultaneous iterative reconstruction technique (SIRT) method. To solve the trade-off problem between time consumption of reconstruction process and accuracy of reconstructed image, the iteration process needs an optimization criterion in algorithm. The simulation results reveal that the SIRT algorithm can offer efficient image reconstructing in DOT system.