Adaptive robotic nursing assistant

What is claimed is: 1. An adaptive robotic nursing assistant comprising: an omni-directional mobile platform; a footrest on the omni-directional mobile platform; a handlebar located above the footrest such that a user standing on the footrest can grasp the handlebar, wherein the handlebar comprises at least one sensor to measure a user interaction force; a display above the handlebar and at least one user input device; a robot manipulator comprising a robotic arm and an end-effector on the robotic arm; and a control system coupled to the omni-directional mobile platform, the control system comprising at least one processor and memory storing executable instructions for the at least one processor to control the omni-directional mobile platform using the at least one sensor on the handlebar; wherein the control system comprises a robot-specific neuroadaptive admittance controller for the omni-directional mobile platform, and wherein the control system is configured to use a feed-forward admittance model that generates a reference motion of the omni-directional mobile platform in response to the at least one sensor on the handlebar, so that the robot-specific neuroadaptive admittance controller tracks the reference motion of the omni-directional mobile platform. 2. The adaptive robotic nursing assistant of claim 1 , wherein the omni-directional mobile platform comprises a base, a set of four wheels attached parallel to each other around a periphery of the base, and a set of four motors configured to individually drive each of the four wheels. 3. The adaptive robotic nursing assistant of claim 1 , wherein the handlebar comprises electronic skin wrapped around at least one gripping portion of the handlebar, and wherein the electronic skin is coupled to the control system. 4. The adaptive robotic nursing assistant of claim 1 , wherein the robotic arm comprises a six degree-of-freedom (DOF) robotic arm or a seven DOF robotic arm, and wherein the end-effector of the robotic arm comprises a gripper. 5. The adaptive robotic nursing assistant of claim 1 , comprising one or more force/torque (FT) sensors coupled to the control system, wherein the control system is configured to execute a whole-body collision detection algorithm using sensor signals from the FT sensors. 6. The adaptive robotic nursing assistant of claim 1 , comprising at least one force/torque (FT) sensor placed on the omni-directional mobile platform underneath an attachment point of the robot manipulator. 7. The adaptive robotic nursing assistant of claim 1 , wherein the control system comprises at least two separate computer systems including a first computer system executing a real-time robot motion control algorithm and a second computing system processing sensor signals from a camera and one or more other sensors. 8. The adaptive robotic nursing assistant of claim 1 , comprising a plurality of sensors distributed in sensor boxes located around a periphery of the omni-directional mobile platform, wherein the plurality of sensors includes at least one infrared (IR) sensor, at least one proximity sensor, and at least one bump sensor. 9. The adaptive robotic nursing assistant of claim 1 , wherein the robot-specific adaptive admittance controller is configured to receive a sensor signal from at least one sensor on the handlebar and to output at least one control signal to the omni-directional mobile platform. 10. The adaptive robotic nursing assistant of claim 9 , wherein the at least one sensor comprises a 6-axis force/torque sensor. 11. The adaptive robotic nursing assistant of claim 1 , wherein the robot-specific adaptive admittance controller is configured to convert a reference motion of the omni-directional mobile platform to a separate wheel reference motion for each wheel of a plurality of wheels of the omni-directional mobile platform using inverse kinematics. 12. The adaptive robotic nursing assistant of claim 1 , wherein the robot-specific adaptive admittance controller comprises a closed-loop neuroadaptive controller. 13. The adaptive robotic nursing assistant of claim 12 , wherein the inner-loop neuroadaptive controller comprises a torque controller configured to emulate a mechanical system with one or more target admittance characteristics. 14. The adaptive robotic nursing assistant of claim 1 , wherein a mechanical adapter mechanism allows the end-effector to hold UV light source or disinfectant liquid sprayer mechanism. 15. The adaptive robotic nursing assistant of claim 14 , wherein the robot arm is configured to operate alongside an autonomous navigation algorithm to navigate facilities and perform sanitization activity on commonly touched surfaces which include but not restricted to doorknobs, tabletops, door-handle, hospital beds and walls. 16. The adaptive robotic nursing assistant of claim 14 , wherein the robotic arm is controlled to hover over surfaces to either spray disinfectants or expose them to UV-C light for disinfection. 17. The adaptive robotic nursing assistant of claim 1 , comprising a riser mechanism to increase/decrease the operating height of the platform on which the robot manipulator is installed. 18. The adaptive robotic nursing assistant of claim 1 , comprising a display unit at the front of the robot to provide visual instructions and feedback during robot operation.