A robot system includes: at least one supporting unit, on which a person is placeable; a robot including a plurality of multi-jointed arms, each of which has a plurality of degrees of freedom, and at least one base provided with the plurality of multi-jointed arms; and at least one type of equipment mountable to the plurality of multi-jointed arms. The robot performs at least two nursing/medical actions on the person by operating the at least one type of equipment.

A lower limb rehabilitation training robot is provided, which includes a bedstead support and a rising bedstead arranged on the bedstead support, and further includes a linear motion device, a push rod device, a bionic leg arranged at one end of a surface of the rising bedstead and hinged to the rising bedstead, and a bed board configured to support a patient and arranged at another end of the rising bedstead. The linear motion device is arranged between the bedstead support and the rising bedstead, is configured to allow the rising bedstead to slide along the bedstead support, and has one lateral surface connected to the bedstead support and another lateral surface hinged to the rising bedstead. The push rod device is configured to drive the rising bedstead to rotate around a hinge point where the rising bedstead is hinged to the linear motion device.

Disclosed is a robot for a repositioning procedure. The robot for a repositioning procedure according to the present invention, comprises: a photographing unit for photographing a plurality of bone images at different angles for each fracture region of a patient and normal region corresponding to the fracture region; an image processing unit for generating a three-dimensional interpolation image for each fracture region and normal region using the plurality of photographed bone images; and a display unit for displaying both the generated three-dimensional interpolation image for the fracture region and the generated three-dimensional interpolation image for the normal region.

An eating aid robot and a method performed thereby are provided. The robot comprises an arm capable of engaging an eating tool at an end of the arm. The arm is moveable to move the eating tool horizontally and vertically, wherein the arm is configured to be positioned with the eating tool in at least two vertical levels. The robot is connectable to a maneuver device which sends a signal to the robot, wherein the arm follows a cycle of different vertical and horizontal movements and pauses when the arm is kept still with the eating tool in at least one of the vertical levels. The method comprises receiving the signal from the maneuver device, and selecting a subsequent movement and/or pause of the cycle for the arm based on in which of the movements or pauses of the cycle the arm currently is when receiving the signal.

A telepresence device may autonomously check patients. The telepresence device may determine the frequency of checking based on whether the patient has a risk factor. The telepresence device may include an image sensor, a thermal camera, a depth sensor, one or more systems for interacting with patients, or the like. The telepresence device may be configured to evaluate the patient's condition using the one or more sensors. The telepresence device may measure physiological characteristics using Eulerian video magnification, may detect pallor, fluid level, or fluid color, may detect thermal asymmetry, may determine a psychological state from body position or movement, or the like. The telepresence device may determine whether the patient is experiencing a potentially harmful condition, such as sepsis or stroke, and may trigger an alarm if so. To overcome alarm fatigue, the telepresence device may annoy a care provider until the care provider responds to an alarm.

A system for controlling a robot by brain electrical signal, includes a screen, an electronic signal detection device, and a host computer. The screen shows a plurality of icons thereon, and the plurality of icons flashes at different frequencies. The electrical signal detection device detects brain electrical signal when one of the plurality of icons is stared. The host computer stores a plurality of personal reference parameters corresponding to the plurality of icons of the screen. The host computer processes the brain electrical signal to get parameters of use, and compares the parameters of use with the plurality of personal reference parameters to choose and execute the icon which is stared.

A companion robot includes a body, a sensing unit, a positioning unit, a network unit, an input unit, a storage device, and at least one processor. The processor controls the companion robot to receive a destination, generate a walking path of the companion robot according to the destination and a current location of the companion robot, obtain a walking direction and a walking speed of a user, and control the companion robot to walk along the walking path according to the walking direction and the walking speed.

The invention relates to a method for using a medical syringe, in which method the medical syringe comprises a cylinder part with retaining lugs or a retaining flange and a needle, and a plunger part which is movable within the cylinder part by moving the plunger rod extending outside the cylinder part with respect to the cylinder part, and the method comprising moving the plunger part with respect to the cylinder part by at least one industrial robot either outwards for drawing liquid into the medical syringe or inwards for injecting the liquid out of the medical syringe. In the method according to the invention, the plunger part is gripped with a gripper configured to prevent the plunger part from turning with respect to the gripper. The invention also relates to an apparatus for using a medical syringe, and a method and an apparatus for dissolving a pharmaceutical substance in a liquid by utilizing the method according to the invention for using a medical syringe.

A robot is disclosed. The robot comprises: a body including a transport means; a head disposed on the body and including a plurality of sensors; and a processor which controls the head on the basis of at least one sensor among the plurality of sensors and acquires information related to a user's health through the sensor of the controlled head.

A telepresence device may autonomously check patients. The telepresence device may determine the frequency of checking based on whether the patient has a risk factor. The telepresence device may include an image sensor, a thermal camera, a depth sensor, one or more systems for interacting with patients, or the like. The telepresence device may be configured to evaluate the patient's condition using the one or more sensors. The telepresence device may measure physiological characteristics using Eulerian video magnification, may detect pallor, fluid level, or fluid color, may detect thermal asymmetry, may determine a psychological state from body position or movement, or the like. The telepresence device may determine whether the patient is experiencing a potentially harmful condition, such as sepsis or stroke, and may trigger an alarm if so. To overcome alarm fatigue, the telepresence device may annoy a care provider until the care provider responds to an alarm.