At present, existing Electric Powered Wheelchairs (EPWs) are limited primarily to use indoors and outdoors with ADA compliant surfaces. EPW users are often exposed to irregular surfaces that include inclined surface (i.e., slopes and, curb-ramps) and/or surfaces with ground changes (i. e. sidewalks, curb drops, speed-bumps, cobblestones). Attempting to drive over such surfaces may cause loss of stability due to wheelchair limitations and user’s limited spatial awareness. Further, surfaces with architectural barriers such as blocked curb-ramps or in bad condition may constrain wheelchair user from accessing sidewalks, limiting their participation in the community. The Mobility Enhancement Robotic (MEBot) EPW was developed to reduce the risk of tips and falls when facing these challenging terrains through advanced mobility applications. During the CDA-1, MEBot was re-designed with a passive-active actuation and suspension (MEBot-PAAS) system to offer a faster and reliable response to maintain stability on inclined surfaces (Grant #A3076-M) compared to commercial EPWs and its previous iteration. While stability was successful, it was noted that its seat orientation significantly changed during sudden changes in the surface. Driving on surfaces with significant ground changes (e.g., sidewalk cracks, curb drops, potholes) may cause MEBot-PAAS to roll-over. Therefore, this CDA-2 proposes to Aim 1) implement MEBot-PAAS capabilities to traverse irregular surfaces (not addressed in the CDA-1) while maintaining stability. Further, Aim 2) will identify its features and clinical limits of use by a group of stakeholders. Aim 3) will evaluate the usability of MEBot-PAAS with Veterans with disabilities in real-world environments to achieve technology readiness to bring it to Veterans. Aim 1 (Year 1-2): Implementation and evaluation of MEBot-PAAS applications (self-leveling and step negotiation) to navigate on irregular surfaces. Aim will be conducted in three phases: Phase 1: Perform engineering changes for implementation of MEBot-PAAS applications: • Develop a dynamic model to reduce Center of Pressure displacement and maintain stability • Incorporate depth sensors for surface characterization and speed limitation ahead of surfaces. • Implement legged-wheel motion to navigate surfaces with significant ground changes. Phase 2: Engineering analysis will evaluate the implemented MEBot-PAAS applications using a ‘rescue dummy’ on controlled irregular surfaces to meet Phase 1 design criteria. Phase 3: Evaluate the performance of MEBot-PASS compared to MEBot-nPAAS (applications de-activated) on controlled irregular surfaces. MEBot-nPAAS will simulate conventional EPWs. We hypothesize that: H1a. MEBot-PAAS will show less center of pressure displacement and H1b. less seat angle variation than MEBot-nPAAS. H1c. A significant difference in vibration levels will be observed between MEBots. Also, participants will report H1d. less lean amplitude, H1e. higher usability and ...