Electrical impedance tomography (EIT) is a powerful tool for mapping the electrical properties of the measured objects. The EIT technique has several potential advantages over the current imaging methods. However, the poor spatial resolution and ill-posed problem restrict the development of an EIT application. In order to improve the image quality, a rotational electrical impedance tomography (REIT) system is proposed to expand the measurement sites by shifting the electrodes. The expanded measurement sites could be regarded as pseudo electrodes. Thus, by successively acquiring the data with adjacent method and rotating the electrodes pair, the independent measurements substantially could be increased. The REIT system is composed of three subsystems, rotary scheme, switches network and measurement system. By injecting the alternating current into the object, a potential will be established on the boundary electrodes of object. The moving scheme is the most important part in the REIT system. 16 compound electrodes are driven by micro-stepping motor to collect additional measurements. A developed Matlab package for the EIDORS project is applied to reconstruct the impedance distribution from boundary measurement. The performance of REIT is explored by using the numerical simulation and trial of a saline-filled phantom. The numerical simulation is provided to verify the feasibility of scanning strategy. A plot of singular values shows the ill-posed degree between the EIT and the REIT. The improvement of spatial resolution is estimated by the edge response and position dependence of the reconstructed image. The impedance images reconstructed from both conventional EIT and REIT are also demonstrated to show the image quality improvement of REIT. REIT also has some practical issues which include metal-wall effect, real-time image reconstruction and the application fields. Some comments and suggestions are given for future work. It is expected to provide more experience and reference material to those who are interested in the field of rotational EIT.