Embodiments of the present disclosure are directed to methods, computer program products, and computer systems of a robotic apparatus with robotic instructions replicating a food preparation recipe. In one embodiment, a robotic control platform, comprises one or more sensors; a mechanical robotic structure including one or more end effectors, and one or more robotic arms; an electronic library database of minimanipulations; a robotic planning module configured for real-time planning and adjustment based at least in part on the sensor data received from the one or more sensors in an electronic multi-stage process file, the electronic multi-stage process recipe file including a sequence of minimanipulations and associated timing data; a robotic interpreter module configured for reading the minimanipulation steps from the minimanipulation library and converting to a machine code; and a robotic execution module configured for executing the minimanipulation steps by the robotic platform to accomplish a functional result.

Described herein are assistant robots that anticipate needs of one or more people (or animals). The assistant robots may recognize a current activity, knowledge of the person's routines, and contextual information. As such, the assistant robots can provide or offer to provide appropriate robotic assistance. The assistant robots can learn users' habits or be provided with knowledge regarding humans in its environment. The assistant robots develop a schedule and contextual understanding of the persons' behavior and needs. The assistant robots may interact, understand, and communicate with people before, during, or after providing assistance. The robot can combine gesture, clothing, emotional aspect, time, pose recognition, action recognition, and other observational data to understand people's medical condition, current activity, and future intended activities and intents.

A multi-arm robot for realizing conversion between sitting and lying posture of patients and carrying patients to different positions is disclosed. The complete robot includes a manipulator module, a trunk module, a chassis moving module and a control module. The manipulator module comprises at least three manipulators, which are connected with the trunk module by linear modules. The trunk module comprises a trunk body and four linear modules, which are connected with the chassis moving module by bolts. The chassis moving module comprises a plurality of omnidirectional wheels and a telescopic counterweight. The control module includes an actuator module, an operation module, an information acquisition module, a motion control module, a data processing module, a communication module and an early warning module.

Provided is a robot including a main body provided with a pair of traveling wheels that are spaced apart from each other in a horizontal direction, a seating body disposed above the main body, a foot supporter disposed on a front lower portion of the main body, at least one front wheel disposed on the foot supporter, and a rear wheel disposed on the main body so as to be closer to a rear end of the main body than a front end of the main body and the traveling wheel is closer to the front end of the main body than the rear end of the main body.

A riding system of a robot which supports a PUI through user authentication to provide convenience to users, and including a server for exchanging authentication information with the robot; a mobile terminal including an application interlocking with the server and for arranging use information of the user through the application and for calling the robot through the application; and a robot storing the authentication information, to authenticate the user through the authentication information when there is a call from the mobile terminal, and deforming according to a body size of the user included in the use information and to allow the user to ride thereon and to move the user to the destination, and a control method thereof.

A wheelchair comprising a mechanical arm for assisting a user is disclosed. The mechanical arm includes a first arm mounted to a first armrest of the wheelchair. The mechanical arm includes a second arm mounted to the first arm via a first swivel rod. The second arm is made to swivel with respect to the first arm. The mechanical arm includes a third arm mounted to the second arm. The third arm is made to swivel with respect to the second arm. The mechanical arm includes claws. The wheelchair includes a controller provided at a second armrest of the wheelchair. The controller is used to operate the first arm, the second arm and the third arm to align the mechanical arm with an object. The controller is also used to operate the claws for gripping and releasing an object.

The invention provides a nursing robot for monitoring critically ill patients, which relates to the field of medical robots, including a robot body, an image taking module arranged at the head of the robot body, a walking device arranged at the bottom of the robot body, a power source module, a processor module, a path finding module, a wireless communication module and a vital sign monitor sampling device arranged in the robot body The video acquisition module is used to collect the video data of the target and send the video data to the cloud server through the wireless communication module. The vital signs monitor sampling module is used to collect the monitoring data of the vital signs monitor and analyze the monitoring data through the processor module to predict the target The development of the disease.

Provided is a method of providing food to a user, the method including determining to provide first food among the food to the user; moving a first gripper to a container that contains the first food, determining whether the first gripper reciprocates in the container, calculating a weight difference value indicating an amount of change in a total weight of the food before and after the reciprocating in response to a determination that the first gripper reciprocates in the container, and determining that the first food is provided to the user based on the weight difference value. In addition, an apparatus for providing food to a user to perform the food providing method is provided. Also, a non-transitory computer-readable storage medium storing programs to perform the food providing method is provided.

A wheeled base includes a housing, two driven wheeled mechanisms positioned on a bottom of the housing and on opposite sides of the housing, at least one passive wheel positioned on the bottom of the housing, actuated feet positioned on the bottom of the housing and configured to move up and down, sensors, and a battery pack arranged within the housing. The two driven wheeled mechanisms each includes a damping mechanism, and each damping mechanism includes at least two dampers configured to absorb impact caused by an upward movement of the housing, and absorb impact caused by a downward movement of the housing.

A proximity sensing autonomous robotic system and apparatus is provided. The robot includes one or more vision modules for viewing the environment for depth perception, object detection, object avoidance and temperature detection of objects. A proximity sensing skin is laminated on one or more parts of the robot. The proximity sensing skin includes a plurality of proximity sensors and mechanical stress sensors for collision avoidance, speed control and deceleration of motion near detected objects, and touch recognition. The proximity sensing skin may include conductive pads for contacting different materials in a composite part to inhibit galvanic corrosion. The robot includes an end effector to which different tools may be attached for performing different tasks. The end effector includes a mounting interface with connections for supplying power and hydraulic/pneumatic control of the tool. All wiring to the sensors and vision modules are routed internally within the robot.