Astronaut sensorimotor impairment is a concern for human spaceflight missions, particularly during and immediately following gravity transitions. When astronauts transition back to a gravitational environment following microgravity exposure, they commonly experience two types of vestibular self-motion illusions termed the tilt-gain and tilt-translation illusions. These vestibular illusions occur when astronauts tilt their heads relative to gravity and result in a sense of tilt over-estimation and/or an illusory sense of translation. This may lead to an improper perception of self or vehicle orientation which may impact functional task performance and vehicle operation. To address this risk, training tools must be developed to prepare astronauts for the vestibular illusions they will encounter post-spaceflight. Galvanic Vestibular Stimulation (GVS) has been shown to produce illusions of tilt and degrade the performance of functional tasks by artificially stimulating the vestibular system. It still remains unclear, however, how well GVS can mimic the vestibular illusions experienced by astronauts post-spaceflight. In support of developing a training tool that can accurately mimic post-flight illusions, this study attempts to systematically quantify the magnitude of orientation perception alteration and the prevalence of side effects experienced during GVS.As a measure of GVS susceptibility, all subjects were seated unrestrained with electrodes attached to the two mastoids. Current waveforms with amplitudes of up to 4mA were applied. Subjects rated sensations of self-motion, skin tingling, metallic taste, and visual flashes at varying current levels. To assess the impact of GVS on tilt perceptions, subjects were also placed in the Tilt Translation Sled (TTS) with heads restrained and then passively tilted ±8° in the roll axis along a pseudorandom sum of sines tilt profile. GVS up to 4mA was applied, in a coupled manner, proportional to the tilt angle, angular velocity,...