According to an aspect, there is provided method for analyzing movement. Initially, information on one or more desired movement properties for a moving element of a mechanical system powered by an electrical machine which is controlled by a drive is maintained in a memory of a wireless sensing device. The wireless sensing device including one or more sensors is detachably fixed to the moving element of the mechanical system. The one or more sensors include one or more kinematic sensors. The wireless sensing device acquire results of a plurality of measurements performed by the wireless sensing device while the moving element is in motion. During the acquiring, the wireless sensing device compares results of the plurality of measurements with the one or more desired movement properties and communicates with the drive to adjust one or more drive parameters based on the comparing.

Systems, methods, and a computer readable medium are provided for configuring a network for a pump monitoring and control system in a fluid production environment. A network can be configured between two or more computing devices configured to receive pump sensor data. A first computing device can receive the pump sensor data to be transmitted via a first wireless transceiver to a second computing device configured with the first wireless transceiver, a second wireless transceiver, and a remote field controller. The second computing device can further transmit the sensor data to a pump monitoring and control server, including a central field controller, via a second network using the second wireless transceiver. The server can process and provide the sensor data.

A robot controller for controlling a robot includes a reception unit configured to receive, by wireless communication, transmission data containing an operation command for the robot, a delay detection unit configured. to detect a delay of the received transmission data from a scheduled arrival time, and a speed setting unit configured to set, when the delay is detected, a movement speed when the robot moves in accordance with the operation command to a 2nd speed which is less than a 1st speed set when the delay is not detected and which is greater than zero.

The invention relates to a housing lid for a field device comprising a screw thread, a receiving and transmitting unit, a battery unit, and a communication interface. The screw thread secures the housing lid to the field device. The receiving and transmitting unit is embodied wirelessly to receive information produced by at least one external unit and to transmit information produced by the field device to the external unit. The battery unit supplies the receiving and transmitting unit and/or the field device with electrical energy. The communication interface is in electrical contact with the battery unit, with the receiving and transmitting unit and via a corresponding communication interface of the field device with the field device.

In one embodiment, a device in a network receives a set of sensor data from a plurality of sensors deployed in a location. The device determines a physical layout for furnishings in the location based on the received set of sensor data. One or more of the furnishings is equipped with one or more actuators configured to move the equipped furnishing in one or more directions. The device generates an instruction for the one or more actuators of a particular one of the furnishings based on the determined physical layout for the furnishings. The device sends the instruction to the one or more actuators of the particular furnishing, to implement the determined physical layout.

Cloud based manufacturing execution systems (MES) and methods thereof used to control, execute, and monitor pharmaceutical or biopharmaceutical production processes and systems are disclosed herein. Consequently, the methods and systems provide a means to quality manufacturing on an integrated level whereby drug or biologic manufacturers can achieve data and product integrity and ultimately minimize cost.

An automated manufacturing process tooling setup assist system includes a controller configured to control movement and positioning of tools to provide a first tool spatial arrangement within a workspace. Responsive to an unsuccessful test process run using the tools in the first tool spatial arrangement, the controller may control movement of the tools so as to replace a tool in the first tool spatial arrangement with another tool configured to perform a function of the tool to be replaced. Responsive to a successful test process run using the tools in the first tool spatial arrangement, the controller may control movement of the tools so as to reposition one or more tools in the workspace to provide a second tool spatial arrangement within the workspace different from the first tool spatial arrangement.

A robot apparatus capable of performing a stable wireless communication is provided. The robot apparatus includes a robot arm including a link, a first control device disposed in the robot arm, a second control device, and a wireless communication unit configured to enable the first control device and the second control device to communicate with each other wirelessly. The wireless communication unit is disposed in the link.

A process device with diagnostics for use in an industrial process includes a process variable sensor or controller element which is configured to sense or control a process variable of a process fluid of the industrial process. Circuitry is coupled to the process variable sensor or control element and configured to measure or control a process variable of the industrial process. A wireless communication adapter includes wireless communication circuitry configured to communicate in the industrial process. The wireless communication circuitry is further configured to receive a process signal from another process device. Diagnostic circuitry is configured to diagnose operation of the industrial process as a function of the sensed process variable and the received process signal.

A drill system including a drill and a secondary computing device. The drill includes a housing, a controller, a wireless transceiver, a motor, and a chuck. The motor, the controller and the wireless transceiver are housed in the housing. The chuck is selectively driven by the motor. The secondary computing device includes a wireless transceiver which allows wireless communication between the drill and the secondary computing device. The secondary computing device further includes a user interface configured to allow an operator to change operating parameters of the drill. The operating parameters are configured to be automatically reset.