Transition metal dichalcogenides monolayers are getting lots of attention as a new type of two dimensional materials for their significant electronic and optical properties such as layer-dependent properties and sizable band gaps. In this thesis, a systematic first principle study of second-order nonlinear optical properties of transition metal dichalcogenides is performed under full-potential projector-augmented wave method. The underlying crystal structures are determined by experimental data. We found that all MX2 monolayers and trilayers including electric field applied MX2 monolayers display significant second-order harmonic generation coefficients. WSe2 monolayer presents the largest second-order harmonic generation susceptibility and it also displays largest linear electro-optical coefficient. Because of the geometric factor, the second harmonic susceptibilities of trilayers are expected to reduce to 1/3 of the monolayers. Due to the interlayer interaction, we found that the does not exactly reduce to 1/3. The prominent features in the spectra of for MX2 monolayers and trilayers are successfully correlated with the features in linear optical dielectric function ɛ(ω) in terms of single- and two-photon resonances. This thesis also investigates the MX2 monolayers under an applied electric field. By applying a vertical electric field to the sheet plane, the mirror symmetry is broken and MX2 monolayers display new nonzero terms of second-order nonlinear optical coefficients. These new nonzero spectra of are also correlated with dielectric function ɛ(ω). Our results show that the new nonzero terms are linearly dependent on the strength of the applied electric field. The new linear electro-optical coefficients are also found.