In this study important aspects of the TASERreg M26trade and X26trade neuromuscular incapacitation device waveforms are simulated, analyzed and contrasted against electrical stimulation with rectangular waveforms (commonly used in therapeutic stimulation devices). Expected skeletal muscle forces evoked by M26trade and X26trade stimulation are simulated also and compared against forces expected with higher or lower frequency trains. The first half-cycle of the M26trade damped 50 kHz sinusoidal wave is the main contributor to stimulation threshold with this device. The pseudo-monophasic component of the X26trade waveform primarily determines threshold for this system, with the leading damped 100 kHz component contributing little in this regard. Simulated isometric forces evoked at 19 Hz with either device are moderately intense (about 46% of maximal). Lower frequencies would likely not provide sufficient levels of contraction to override volitional motor control.