A system for monitoring and controlling a manufacturing environment is disclosed. Aspects discussed include beacons broadcasting identifying information for aspects of the manufacturing environment such as workstations, manufactured items, machines, equipment, and people. The identifying information may be used to generate reports about the operation of these and possibly other aspects, as well as provide control options for changing the manufacturing environment. Employees may move about the environment to visually monitor activities taking place, while the system may automatically query for additional information about the tools, equipment, people encountered in the environment. Control options for changing aspects of the manufacturing processes may also be automatically displayed as well.

According to one embodiment, a system includes a processor and a transmitter. The processor is configured to generate a first control signal including a first instruction to operate at least part of a terminal with in a first validity and generate a second control signal including a second instruction to operate at least part of the terminal within a second validity period after an operation of the at least part of the terminal in accordance with the first instruction. The transmitter is configured to transmit the first control signal to the terminal at first timing and transmit the second control signal to the terminal at second timing after the first timing. An end of the first validity period is after the second validity timing.

A technique for providing reliable wireless communication between a robot (104) and a robot controller (102) in a cloud robotics system is disclosed. A method implementation of the technique is performed by a primary connectivity component (106) supporting multipath transmission over a plurality of wireless transmission paths to establish connectivity between the robot (104) and the robot controller (102). The method comprises triggering determining (S402) a robot sensitivity value indicating a degree of operation sensitivity of the robot (104) to a transmission failure between the robot (104) and the robot controller (102), and triggering configuring (S404) use of one or more of the plurality of wireless transmission paths for communication between the robot (104) and the robot controller (102) depending on the determined robot sensitivity value.

A router device for matching operations of client devices hosted on a network with contextual automations gathers device information from client devices that are connected to the router device via a wireless local area network (WLAN), wherein the client devices include a user device and one or more other devices, sends the device information collected from the client devices to a first remote server, receives device identification information of the client devices from the first remote server based on the device information, respectively, sends the device identification information of the client devices to a second remote server, receives a list of condition-based automations (CBAs) that are available and applicable for one or more of the client devices from the second remote server based on the device identification information, and sends the list of CBAs to the user device for presentation via a display.

Smart Wireless Adapters are provided herein for establishing communication between measurement devices and a measurement control and data acquisition system in an industrial system. In one aspect, a method of establishing communication between a Pneumatic or Analog measurement device and the measurement control and data acquisition system includes providing a Pneumatic or Analog measurement device and providing a Smart Wireless Adapter capable of electrically and mechanically coupling to the Pneumatic or Analog measurement device. The Pneumatic or Analog measurement device is configured to measure one or more parameters in the industrial system and provide a value or signal indicative of the measured parameters at an output of the Pneumatic or Analog measurement device. Additionally, the Smart Wireless Adapter is coupled to receive the value or signal from the Pneumatic or Analog measurement device and configured to wirelessly transmit data indicative of the value or signal to the measurement control and data acquisition system.

A system capable of communicating with a terminal includes a processor and a transmitter. The processor is configured to generate a first control signal including a first target position to operate at least part of the terminal and generate a second control signal including a second target position to operate at least part of the terminal after an operation of the at least part of the terminal in accordance with the first target position. The transmitter is configured to transmit the first control signal to the terminal at a first timing and transmit the second control signal to the terminal at a second timing after the first timing. The first target position is farther than a position which the at least part of the terminal is to reach at the second timing.

The present disclosure relates to condition monitoring of wireless networks in industrial plant, wherein a wireless network has two or more wired gateways and a plurality of access nodes connected wirelessly with at least one wired gateway. Here, each access node is associated with at least one field device of the industrial plant. The condition monitoring is performed with an industrial device connected with the two or more wired gateways. The condition monitoring comprises periodically receiving information associated with packet transfer, channel access, and connection links for each node of the plurality of access nodes and each wired gateway. One or more parameters are estimated based on the received information, to determine connectivity status of the field devices in the industrial plant. The connectivity status is rendered on a user interface of an industrial device.

A method for use in an automated wireless industrial system comprising a device (100, 210,220) configured to act as a control node and at least one field level device (100), 230), wherein the method comprises: issuing a control communication (510); inserting at least one5 time delay (tk) to the control communication (520); noting (530) the communication time (TCL) for the communication; comparing (540) the time for communication (TCL) to an expected time for communication (TR); and determining (550) if any of the at least one time delay (tk) should be adapted, and if so, adapting at least that time delay (560).

A system for monitoring and controlling a manufacturing environment is disclosed. Aspects discussed include beacons broadcasting identifying information for aspects of the manufacturing environment such as workstations, manufactured items, machines, equipment, and people. The identifying information may be used to generate reports about the operation of these and possibly other aspects, as well as provide control options for changing the manufacturing environment. Employees may move about the environment to visually monitor activities taking place, while the system may automatically query for additional information about the tools, equipment, people encountered in the environment. Control options for changing aspects of the manufacturing processes may also be automatically displayed as well.

A system for monitoring and controlling a manufacturing environment is disclosed. Aspects discussed include beacons broadcasting identifying information for aspects of the manufacturing environment such as workstations, manufactured items, machines, equipment, and people. The identifying information may be used to generate reports about the operation of these and possibly other aspects, as well as provide control options for changing the manufacturing environment. Employees may move about the environment to visually monitor activities taking place, while the system may automatically query for additional information about the tools, equipment, people encountered in the environment. Control options for changing aspects of the manufacturing processes may also be automatically displayed as well.