The study aimed to develop a sustainable and innovative system with the purpose of improving mobility assistance, quality of life, and preventing falls for individuals with limited mobility. Specifically, it aimed to solve the challenges faced by users in navigating uneven surfaces and performing daily tasks, relying heavily on caregivers and therefore losing independence. The investigation involved drafting blueprints, prototyping, and iterative design refinement, integrating advanced features such as solar panels for sustainable power, robotic arms for enhanced task support, and shock-absorbent components to improve stability. The Robotic Fall Prevention and Mobility Assistance System then had its stability, surface adaptability, task assistance, and battery efficiency tested and evaluated through standardized tests. Results and data gathered indicated that the RoboTech Chair performed optimally on flat surfaces and showed strong functionality on uneven terrain, achieving an average mobility efficiency of over 90% across varied tests. However, challenges in battery longevity and terrain adaptability emerged as it struggled to perform when the battery had dropped below 80%, highlighting areas for future improvement. Data obtained from the study demonstrate the Robotic Fall Prevention and Mobility Assistance System's potential as a viable alternative for assistive mobility solutions, combining functionality with sustainability. Further research could enhance the system’s efficiency in real-world scenarios, particularly in extending battery life, optimizing performance on rugged surfaces, and using the data to translate into a full-scale robot.