A robot-connected IoT-based sleep-caring system includes a sleep-caring robot and an IoT system. The sleep-caring robot includes environment monitoring, physiology monitoring, sleep monitoring, sound, lighting and electricity control, a smart storage compartment, central data processing, and machine arms. The IoT system senses and executes instructions from the sleep-caring robot, thereby catering to bedroom activities of the user.

A robot-connected IoT-based sleep-caring system includes a sleep-caring robot and an IoT system. The sleep-caring robot includes environment monitoring, physiology monitoring, sleep monitoring, sound, lighting and electricity control, a smart storage compartment, central data processing, and machine arms. The IoT system senses and executes instructions from the sleep-caring robot, thereby catering to bedroom activities of the user.

This display system comprises: a display unit for displaying a screen for a setting or a status check; a storage unit for storing a dictionary file corresponding to a display language displayed on the display unit; and an item display transition unit for causing, on the basis of the dictionary file, a display of an item in a particular part on the screen to transition to another message expressed in the stored display language.

In various embodiments, the present disclosure relates to robot systems configured to operate on a cell tower to inspect, install, reconfigure, and repair cellular equipment. The present disclosure provides a robot for performing audit tasks of cell towers. The robot includes a body portion configured to hold various electronic components of the robot including monitoring equipment disposed thereon, one or more arms extending from the body portion adapted to manipulate components of a cell tower and to facilitate movement of the robot on the cell tower, and wireless interfaces adapted to receive control signals from a Virtual Reality (VR) system allowing wireless control of the robot. The robot is configured to be controlled by one of a user in a remote location, a user at the cell tower site, and autonomously via direct programing.

A system includes a robotic drive comprising a plurality of cassettes, each cassette to move an elongated medical device (EMD) loaded therein, and an input module to issue instructions to the robotic drive. The input module includes a first two or more selection buttons to select a first two or more EMDs loaded in respective ones of the plurality of cassettes, a first control actuatable to cause issuance of an instruction to the robotic drive to simultaneously move each of the first two or more EMDs linearly, and a second control actuatable to cause issuance of an instruction to the robotic drive to simultaneously rotate each of the first two or more EMDs.

A system includes a robotic drive comprising a plurality of cassettes, each cassette to move an elongated medical device (EMD) loaded therein, and an input module to issue instructions to the robotic drive. The input module includes a first two or more selection buttons to select a first two or more EMDs loaded in respective ones of the plurality of cassettes, a first control actuatable to cause issuance of an instruction to the robotic drive to simultaneously move each of the first two or more EMDs linearly, and a second control actuatable to cause issuance of an instruction to the robotic drive to simultaneously rotate each of the first two or more EMDs.

A control system for a surgical robot is provided. The control system includes a first embedded computer and a second embedded computer configured to receive status information from the first embedded computer. The status information includes a status of zero-return for a surgical tool driving module or an imaging tool driving module. The control system also includes a host computer configured to receive the status information from the second embedded computer. The surgical tool driving module or the imaging tool driving module includes a controller, a motor connected with a first coupling and configured to drive the surgical tool or an imaging tool, and a zero point switch configured to detect whether the first coupling is at a zero position. The controller is configured to transmit the status of zero-return to the first embedded computer based on whether the first coupling is at the zero position.

A control system for a surgical robot is provided. The control system includes a first embedded computer and a second embedded computer configured to receive status information from the first embedded computer. The status information includes a status of zero-return for a surgical tool driving module or an imaging tool driving module. The control system also includes a host computer configured to receive the status information from the second embedded computer. The surgical tool driving module or the imaging tool driving module includes a controller, a motor connected with a first coupling and configured to drive the surgical tool or an imaging tool, and a zero point switch configured to detect whether the first coupling is at a zero position. The controller is configured to transmit the status of zero-return to the first embedded computer based on whether the first coupling is at the zero position.

A system for automating a process using robotic process automation code includes a memory device for storing program code, and at least one processor device operatively coupled to the memory device. The at least one processor device is configured to execute program code stored on the memory device to process, based on a contextual dictionary, a process description document associated with a process to be automated by a robotic process automation system, automatically generate robotic process automation code based on the processing, and execute the robotic process automation code for automating the process.

A system for automating a process using robotic process automation code includes a memory device for storing program code, and at least one processor device operatively coupled to the memory device. The at least one processor device is configured to execute program code stored on the memory device to process, based on a contextual dictionary, a process description document associated with a process to be automated by a robotic process automation system, automatically generate robotic process automation code based on the processing, and execute the robotic process automation code for automating the process.