With the progress of science and technology, people can use computers to deal with and solve a lot of engineering problems for the purposes of raising efficiency, lowering costs, etc. Still there are a lot of problems in many fields that require to carry out experiments and to use approximate solutions. Wind engineering belongs to the latter. Wind tunnel tests usually provide the most reliable design wind loads in current wind engineering practice. Nevertheless, wind tunnel tests are expensive and time consuming. It is very desirable to save resources and to obtain relatively accurate design wind loads at preliminary design stage. It can save a lot of time for engineers. The reported research employed artificial neural networks to predict wind spectra and calculate wind loadings for rectangular cross-section buildings. Similar buildings can be used to anticipate the relevant information of the target building, and proceed to complete the preliminary design. In this thesis, MATLAB was used to implement the Radial Basis Function Neural Networks (RBFNN) constructed. The training and validation of the RBFNN cover alongwind, acrosswind and torsional wind force spectra in all three exposure conditions. For all three kinds of exposures, the spectrum errors under the most frequently used frequencies (0.15 ~ 0.4) are less than 3.96% for the training set and less than 4.07% for the validation set. As for the dynamic responses, the errors are less than 11.62% for the training set and less than 13.60% for the validation set. These results show that using aerodynamic database constructed from wind-tunnel test data to train RBFNN is a prospective approach to predict wind spectra.