A robotic system includes retrieval of a priori stimulus based on an input that indicates a current health state and a target health state of a user. A set of test stimuli specific for the user is determined and a stimulus device is controlled to provide the set of test stimuli to the user. A first set of responses within the body of the user and a second set of responses discernible on the body of the user are determined, and a set of stimulus parameters for the stimulus device is calibrated based on the combination of the first set of responses, the second set of responses, the current health state, the target health state, and a trained AI-based system. A new stimulus is applied to a portion of the body of the user that shifts a condition of the user from the current health state towards the target health state.

A method and system to monitor and autonomously configure an intravascular assembly without medical staff involvement or presence. In this solution, a robotic device is associated with an intravascular assembly, which has tubing through which fluids are delivered intravenously. Monitoring of the tubing is initiated. In response to the monitoring, an errant flow through the tubing is detected; typically, the errant flow results from one of: a kink or twist in the tubing, an air bubble in the tubing, an occlusion or clot in the tubing, and pressure variations. In response to detecting the errant flow, and in advance of an audible alarm being generated in association with the intravascular assembly, a command is then issued to the associated robotic device. The command is configured to initiate, by the robotic device, physical engagement with and mechanical manipulation of the tubing, thereby remediating the errant flow automatically.

There is provided a lifting robot suitable for lifting and transferring a person. Especially there is provided a patient lift apparatus with collapsible vertical and horizontal columns that allows the apparatus to change its height and width. Specifically there is provided a patient lifting robot having a frame for lifting and carrying persons. The frame has adjustable length and width, since the frame comprises two vertically collapsible columns for adjusting the height of the frame, and one horizontally collapsible beam for adjusting the width of the frame.

A walking assistant robot, comprising a main frame body (1), a foot walking mechanism for alternating walking, an auxiliary device (2) and a control device; the walking mechanism, the auxiliary device (2) and the control device are all disposed on the main frame body (1); the control device is connected with the walking mechanism; the auxiliary device (2) includes auxiliary feet (201), and the auxiliary feet (201) are disposed in front of and/or behind the walking mechanism along the walking direction. The foot walking mechanism is used to realize the basic function of the robot walking forward; auxiliary feet (201) are disposed in the walking direction such that the walking mechanism still has, at the moment of foot alternation, multiple supporting points in contact with the ground. Therefore, the mechanism is slip-and-fall-resistant, stable and reliable and guarantees the user safety.

A telepresence robot may include a drive system, a control system, an imaging system, and a mapping module. The mapping module may access a map of an area and tags associated with the area. In various embodiments, each tag may include tag coordinates and tag information, which may include a tag annotation. A tag identification system may identify tags within a predetermined range of the current position and the control system may execute an action based on an identified tag whose tag information comprises a telepresence robot action modifier. The telepresence robot may rotate an upper portion independent from a lower portion. A remote terminal may allow an operator to control the telepresence robot using any combination of control methods, including by selecting a destination in a live video feed, by selecting a destination on a map, or by using a joystick or other peripheral device.

A humanoid hugging assembly includes a humanoid animatronic that has a torso, a pair of arms and a pair of hands each is disposed on a respective one of the arms. The arms are positionable in a resting position having the arms extending downwardly along the torso and having a palm of each of the hands facing the torso. Each of the arms is positionable in a hugging position has each of the arms is crossed in front of the torso wherein the pair of arms is configured to embrace the user. A motion sensor is integrated into the humanoid animatronic to sense motion of the user approaching the humanoid animatronic. A motion unit is integrated into the humanoid animatronic and the motion unit actuates each of the arms into the hugging position when a predetermined duration of time has passed when motion sensor senses motion.

A control device for a robot that can decrease damage when the robot falls forward or rearward and can be applied to an assist robot is provided. A controller 20 of a control device 1 determines whether a robot 2 is in a fall start state in which the robot starts to fall in one of a forward direction and a rearward direction based on detection signals from sensors 21 to 23 (STEP10 to STEP20), performs knee joint control such that a part in the one direction of a knee joint and a hip joint comes into contact with a walking surface (STEP45 and STEP63), and performs hip joint control such that the center of gravity GC_u of an upper body moves in the direction opposite to the one direction (STEP46 and STEP6 4) when it is determined that the robot 2 is in the fall start state.

A robotic medical system can include a patient platform. The patient platform includes a tilt mechanism. The tilt mechanism can include a lateral tilt mechanism and a longitudinal tilt mechanism. The lateral tilt mechanism can include a tilt plate and a pivot housing. A linear actuator mounted on the tilt plate can apply a linear force to the pivot housing. The lateral tilt mechanism can also include a first linear guide that extends along a first axis, and the pivot housing can translate along the first linear guide. Application of the linear force to the pivot housing tilts the tilt plate by causing the pivot housing to translate along the first linear guide.

A sitting motion assist system for assisting a sitting motion of a patient changing their posture from a standing posture to a sitting posture includes a care belt, a knee-bending adviser, and a pulling mechanism. The care belt can be put on the patient and includes a hold mechanism including a first holder capable of holding the neck or shoulder of the patient and a second holder capable of holding their lower back, and a coupler capable of being positioned on their chest and coupled to the hold mechanism. The knee-bending adviser advises the patient to perform a knee-bending motion. The pulling mechanism is coupled to the hold mechanism via the coupler and pulls the care belt downward and slightly forward relative to the patient after the advice by the knee-bending adviser, and thereafter pushes the care belt downward and slightly backward to assist the sitting motion.

A portable urinal designed to collect urine from one location and deposit that urine into another location for disposal (e.g. drain). The invention enables a person to remain sedentary while urinating and waste disposal.