The investigation of twin boundary (TB) dynamics on the level of individual TBs has attracted recently more attention because the TB mobility dictates the dynamic properties of magnetic shape memory-based devices. In the present study, we investigated both type 1 and type 2 single TB motion in 5M Ni-Mn-Ga martensite under pulsed magnetic field actuation. A mathematical model was developed to describe the motion and retrieve the twinning stress (TS) values from the experimental data. We found a strong dependence of the dynamic TS on TB velocity and type. For type 1 interface, the TS drastically increases from its quasi-static value of ~0.6 MPa to ~3.2 MPa, thus limiting the TB velocity to 3-4 m/s measured in saturation field. Type 2 TBs show a gradual increase of the TS from ~0.1 MPa to ~2 MPa, reaching saturation velocities of ~33-39 m/s. Our results show that type 2 interfaces are preferable in applications demanding high actuation speeds and frequencies.