The macroscopic traffic flow models which account for the flow rate, density or speed of groups of vehicles on the roads, are advantageous to its high efficiency. On the contrary, the microscopic traffic flow models deal with the stimulation terms to spacing or relative speed between individual vehicles and respond to its acceleration or deceleration. The advantage of them lie in describing detailed vehicle behaviors and high accuracy. Therefore, it is necessary to be confronted with a trade-off between efficiency and accuracy when conducting mixed traffic flow models simulation. This study takes the prevailing mixed traffic of cars and motorcycles on urban streets as the background. Firstly, based on the mixed traffic cell transmission models (MCTM), proposed by C.W. Hsieh (2010), to simulate platoons of vehicles with traffic flow transference within segment cells to reduce simulation time. Secondly, based on the cellular automaton and microscopic lane changing principles in mixed traffic, proposed by Lan et al.(2009、2010), to simulate platoons of vehicles with parallel driving and lane changing behaviors in close proximity to the intersection. In order to make these two models stated above integrate properly, this study develops a macro-micro traffic flow models with a transmission interface design, which combines advantages over both models and takes characteristics of mixed traffic into consideration. Moreover, real data of mixed traffic on urban streets is collected. To obtain all the vehicle trajectories in the experimental segment and calculate numbers of vehicles in each cell at each time step through analyzing them. The proposed model in different scenarios is assumed and divided into seven kinds of macro-micro proportions. The efficiency index is measured by CPU time and accuracy index is by SMAPE values to validate the proposed model. This study puts emphasis on the simulation effectiveness of interfaces in different positions of the segment and tries to find out the best one. The results demonstrate that the macroscopic traffic flow models is conductive to reduce the simulation time and improve efficiency. The microscopic traffic flow models make for accuracy. Under a balanced of efficiency and accuracy, the best position of the interface measured by simulation effectiveness is thirty to sixty meters apart from the intersection. It is supposed to transfer the model from macroscopic to microscopic before the traffic flow is interrupted.