In this thesis, the equivalent circuit parameters of the primary lattice type acoustic resonator are extracted for the lattice combination architecture by using both analytical and numerical solutions. Based on this method, the S-parameter frequency response of the filter is made to meet the system specifications as much as possible for the lithium tantalum based on the YX 〖42〗^° cut angle (electromechanical coupling coefficient of about 6%). For single-stage lattice acoustic wave filter, this thesis provides two methods for design in addition to numerical solution. One is to obtain the analytical solution by traditional filter synthesis theory and derive the LC value of LC resonator by ideal Chebyshev response, when the passband has a small fractional bandwidth (FBW) or low return loss (RL), i.e., the approximation formula of the BVD model. Another method is parametric analysis, which is used to obtain the optimal design curve for the passband, providing the designer with the relationship between the specifications and design parameters and the limits of the optimal design specifications for the passband. For the extended multi-stage design, the study further uses the numerical optimization method to design two- and three-stage lattices and a modified lattice configuration to make the designed filter frequency response meet the system specifications as much as possible given the specific acoustic resonator characteristics and material constraints. Compared with the results in the literature, the bandwidth of the ladder type and the conventional lattice type can be designed with a limit of about 5%; the bandwidth of the modified lattice configuration is not limited by the electromechanical coupling coefficient, and the maximum bandwidth can be designed with a return loss of 10 dB or more. Finally, with a three-stage lattice-type for practical application in the 5G band, the designed bandwidth range from 1.9% to 5.1%, which can meet the requirement of passband return loss of more than 10 dB and also has good out-of-band performance.