A robot system that includes a robot and a remote station. The remote station may be a personal computer coupled to the robot through a broadband network. A user at the remote station may receive both video and audio from a camera and microphone of the robot, respectively. The remote station may include a display user interface that has a variety of viewable fields and selectable buttons.

Upper arms are fixed to drive shafts of a pair of drive sources at or near respective left and right hip joints. The upper arms are coupled to an upper body trunk harness by first passive rotary shafts via third passive rotary shafts, and are mounted to a lower body trunk harness by a mounting device. Lower arms are fixed to drive source bodies, and are coupled to thigh harnesses by second passive rotary shafts via fourth passive rotary shafts. The first and second passive rotary shafts and third and fourth passive rotary shafts are angularly displaceable about axial lines in a lateral direction of the wearer and axial lines in an anteroposterior direction of the wearer, respectively. An acceleration/angular speed sensor fixed to the lower body trunk harness detects an acceleration of the body trunk in a vertical direction by landing of a foot.

A robotic assistant includes a wheeled base, a storage unit including drawers, a foldable arm connected to a top of the storage unit and including an end of arm tooling (EOAT) connected to a distal end of the foldable arm, an elevation mechanism positioned on the wheeled base and used to move the storage unit up and down, and a control system that receives command instructions. In response to the command instructions, the control system is configured to move the wheeled base, open or close the one or more drawers, actuate movement of the foldable arm and the EOAT to pick up and place external objects from/to a determined location, and control the storage unit to move up/down.

A handheld device is provided. The handheld device includes: a functional body to be used by a user; a handle provided with a first detection circuit configured to detect a movement state of the handle to acquire hand tremor information about a hand of the user; a movable connector through which the functional body is movably connected to the handle in such a manner that the functional body is capable of moving relative to the handle; a movement mechanism connected to the functional body and configured to drive the functional body to move relative to the handle; and a control circuit configured to control an operating state of the movement mechanism in accordance with the hand tremor information acquired by the first detection circuit, to drive the functional body to perform compensating movement relative to the handle, thereby to maintain the functional body at a selected position.

An assistance device that more appropriately identifies a user using speech. The assistance device is provided with a speech detector, a name acquiring section that acquires a name of a person based on speech detected by the speech detector, and a user identifying section that identifies a care receiver who is a user of the assistance device based on the name acquired by the name acquiring device.

A patient transfer system is provided. The patient transfer system comprises a lifting mechanism, an actuator unit attached to the lifting mechanism, two conveyors attached to the actuator unit such that they extend from the actuator unit in a forklift fork-like manner, wherein the conveyors respectively have a conveyor belt and opposite reversing ends reversing the conveyor belt. The actuator unit is configured to move the conveyors such that the reversing ends facing each other are linearly movable towards and apart from each other.

An autonomous companion mobile robot and system may complement the intelligence possessed by a user with machine learned intelligence to make a user's life more fulfilling. The robot and system includes a mobile robotic device and a mobile robotic docking station. Either or both of the mobile robotic device and the mobile robotic docking station may operate independently, as well as operating together as a team, as a system. The mobile robotic device may have an external form of a three-dimensional shape, a humanoid, a present or historical person, some fictional character, or some animal. The mobile robotic device and/or the mobile robotic docking station may each include a fog Internet of Things (IoT) gateway processor and a plurality of sensors and input/output devices. The autonomous companion mobile robot and system may collect data from and observe its users and offer suggestions, perform tasks, and present information to its users.

Grippers for a picking device for drug packages and methods for operating the picking device are provided. The gripper has a tray table extending in a first and a second horizontal direction with an end portion with an arcuate front extending in the second direction, the end portion forming the loading and unloading front and wherein the tray table and the end portion define an upper bearing surface. The gripper further includes a transport device arranged above the tray table and movable in the first horizontal direction for moving drug packages from a horizontal storage surface onto the tray table, and at least one sensor coupled to a control device and arranged in the end portion below the bearing surface and capable of determining the presence of a drug package in its detection area.

Disclosed is a mecanum wheel, including a mecanum wheel body and a drive device. A wheel axle hole is formed in the mecanum wheel body. The drive device is partially or completely arranged in the wheel axle hole. The axis of a connecting shaft of the drive device is collinear with a rotary shaft of the mecanum wheel body, and the mecanum wheel body rotates along with a housing of the drive device. Further disclosed are a mecanum wheel with a shock absorbing device, a chassis including at least one pair of mecanum wheels, and an assistant robot including a chassis.

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.