Spin-orbit torque (SOT) induced domain wall (DW) motion in non-magnet/ferromagnet/oxide systems is a promising concept for three terminal spintronics devices. The asymmetry of stack structure results in an interfacial Dzyaloshinskii-Moriya interaction (DMI) which plays a pivotal role for fast SOT-driven DW motion. Thus, understanding the manifestation of DMI-induced effective field (H_DMI) is important. Thermally-activated DW motion under magnetic fields (H_Z and H_X) is proposed to offer quantitative information about H_DMI. However, the role of H_DMI from this regime is greatly debated and demands a quantitative comparison of H_DMI between dynamically different regime of DW motion, i.e., flow regime. Multilayers utilized in this study are W(5)/CoFeB(1.1)/MgO(2)/Ta(1) (W/CoFeB) and Ta(4)/Pt(3)/Co(0.3)/Ni(0.6)/Co(0.3)/MgO(1.5)/Ru(1) (Pt/[Co/Ni]) (in nm). To evaluate DMI from thermally-activated regime, we investigate H_X dependence of bubble expansion under H_Z. DW velocity (v) vs H_X curve indicates H_DMI= 14 ± 5 mT for W/CoFeB, whereas miniscule value (H_DMI ≈ 0 ± 10 mT) for Pt/[Co/Ni]. We also investigate H_X dependence of current-driven DW motion in flow regime for both the samples. The results shows non-zero DMI for both the structures. Only the result for Pt/[Co/Ni] in thermally-activated regime does not agree with previous study. We find that an accurate determination of DMI strength is possible only when DW motion satisfies a creep scaling law for the thermally-activated regime, whereas the flow-regime experiment is versatile for quantification of DMI.