The ISM band at 2.4? GHz has mostly been used or planned for indoor systems. This band is also attractive for outdoor systems owing to the ease of the system deployment, as no frequency licenses are required. In this paper, a multiple successive internal multireflection model is used to estimate the complex electric permittivity at 2.4? GHz band. To obtain the data, measurements are performed at 160? MHz bandwidth centered about 2.4? GHz using a vector network analyzer, which provides information about the amplitude and phase of transmission coefficient. Several samples of each material are measured and the results vary from sample to sample. It has also been found that some obstacles have polarization behaviour. This band is also attractive for outdoor systems due to the ease of the system deployment, as no frequency licenses are required. In this paper, a multiple successive internal multireflection model is used to estimate the complex electric permittivity at 2.4 GHz band. To obtain the data, measurements are performed at 160 MHz bandwidth centered about 2.4 GHz using a vector network analyzer, which provides information about the amplitude and phase of transmission coefficient Several samples of each material are measured and the results vary from sample to sample. It has also been found that some obstacles have polarization behavior.