Expressions for the molecular orientation of long and short chains in bimodal networks, SL and Ss, are derived based on the theory developed by Kloczkowski et al. (Macromolecules 1991, 24, 3266) for regular bimodal phantom networks and compared with those (S-L degrees and S-S degrees) occurring in,corresponding unimodal networks. The changes in segmental orientation of the respective chains in bimodal networks relative to their unimodal counterparts, expressed as the ratio S-L/S-L degrees or S-S/S-S degrees, are shown to be independent of macroscopic strain and intrinsic chain configurational characteristics but depend essentially on network topology and composition. The latter are accounted for by two variables : the ratio xi of the molecular weights of short chains to that of long chains, and the number phi(S) and phi(L) of short and long chains at each junction. Results of the formulation show that the long (short) chains in the bimodal network orient more (less) than those in the corresponding unimodal network. These differences in the orientation behavior of the two chains arise from differences in fluctuations of chain dimensions that, in turn, affect the microscopic strain of each component. Predictions of the theory are compared in the following paper with results of Fourier transform infrared measurements on well-defined poly(dimethylsiloxane) networks.