Various embodiments of this disclosure provide a method and apparatus for managing a field device on a network. The method includes detecting, at a processing device, a connection of the field device in an industrial process control and automation system. The method also includes receiving data, from the field device, including payload information related to the field device in the industrial process control and automation system. The method also includes determining, at the processing device, whether the field device uses a specific protocol based on the data. The method also includes responsive to determining that the field device uses the specific protocol, generating, at the processing device, a soft modem instance. This method also includes termination of soft modem instance if the field device gets disconnected. The method also includes demodulating and extracting, using the soft modem instance, the payload information from the data.

Provided is a process, including: receiving, via the network interface, from a remote user device, a command to change a state of the fluid-handling device to a target state; translating the received command into a translated command operative to cause a local controller of the fluid-handling device to drive the fluid-handling equipment to the target state, the local controller being responsive to the command and feedback from the fluid-handling device indicative of whether the fluid-handling device is in the target state; and sending the translated command to the local controller

The invention relates to an apparatus configured to receive an input message via the first interface. The input message having a first layer structure and containing an information piece associated with the top layer of the first layer structure, extracting the information piece from the input message by passing the input message through a protocol stack associated with the first layer structure from bottom to top, examining the extracted information piece to obtain an examination result, generating an output message by passing the extracted information piece or an information piece generated on the basis of the extracted information piece through a protocol stack associated with a second layer structure from top to bottom, and sending the output message via the second interface. The generating and/or the sending of the output message are performed as a function of the examination result.

Provided is a process, including: receiving, via the network interface, from a remote user device, a command to change a state of the fluid-handling device to a target state; translating the received command into a translated command operative to cause a local controller of the fluid-handling device to drive the fluid-handling equipment to the target state, the local controller being responsive to the command and feedback from the fluid-handling device indicative of whether the fluid-handling device is in the target state; and sending the translated command to the local controller.

The subject matter disclosed herein describes a switch embedded in a motor controller and a network protocol executing on the switch to provide communication between devices connected to the motor controller in a motor drive application. The embedded switch is configured to communicate via separate ports with an external controller, a network interface for the motor controller, additional motor controllers, and with the motor or other devices mounted on the motor. The network protocol includes a first tier for data that requires deterministic delivery at a high data rate, a second tier for data that requires a high delivery rate but is also tolerant of some variation in delivery time, and a third tier for data that may be delivered at a slower data rate. The embedded switch receives data at any port, identifies the communication tier to which the data belongs, and delivers it to another port accordingly.

A universal metering cabinet (UMC) apparatus comprises an input/output (I/O) interface configured to receive at least two data streams, each of the at least two data streams received from one of at least two sensors, and each of the at least two data streams having a different connectivity protocol. The UMC further comprises a customizable programmable interface coupled with the I/O interface and configured to convert the connectivity protocol of each of the at least two data streams into a same uniform connectivity protocol. A method comprises receiving, from the UMC, at least one data stream that includes data from at least two sensors, and receiving, from at least one server, data related to an environment around the at least two sensors. The method further comprises performing data cleansing on the data stream and the data to generate validated data and performing prognostic modeling on the validated data.

The subject matter disclosed herein describes a switch embedded in a motor controller and a network protocol executing on the switch to provide communication between devices connected to the motor controller in a motor drive application. The embedded switch is configured to communicate via separate ports with an external controller, a network interface for the motor controller, additional motor controllers, and with the motor or other devices mounted on the motor. The network protocol includes a first tier for data that requires deterministic delivery at a high data rate, a second tier for data that requires a high delivery rate but is also tolerant of some variation in delivery time, and a third tier for data that may be delivered at a slower data rate. The embedded switch receives data at any port, identifies the communication tier to which the data belongs, and delivers it to another port accordingly.

Provided is a process, including: receiving, via the network interface, from a remote user device, a command to change a state of the fluid-handling device to a target state; translating the received command into a translated command operative to cause a local controller of the fluid-handling device to drive the fluid-handling equipment to the target state, the local controller being responsive to the command and feedback from the fluid-handling device indicative of whether the fluid-handling device is in the target state; and sending the translated command to the local controller.

A fieldbus coupler for coupling a local fieldbus network utilizing a first fieldbus protocol to a foreign field device or foreign fieldbus network through an interconnecting wired or wireless network transmission line that utilizes a second fieldbus protocol different from the first fieldbus protocol includes a first circuit configured to communicate over the local fieldbus network using the first fieldbus protocol, a second circuit configured to connect the fieldbus coupler with the interconnecting network transmission line and communicate over the interconnecting network transmission line using the second fieldbus protocol, and a third circuit configured to communicate with the first and second circuits and capable of transmitting data to and from the first and second circuits to enable communications between the local fieldbus network via the interconnecting network transmission line.

The subject matter disclosed herein describes a switch embedded in a motor controller and a network protocol executing on the switch to provide communication between devices connected to the motor controller in a motor drive application. The embedded switch is configured to communicate via separate ports with an external controller, a network interface for the motor controller, additional motor controllers, and with the motor or other devices mounted on the motor. The network protocol includes a first tier for data that requires deterministic delivery at a high data rate, a second tier for data that requires a high delivery rate but is also tolerant of some variation in delivery time, and a third tier for data that may be delivered at a slower data rate. The embedded switch receives data at any port, identifies the communication tier to which the data belongs, and delivers it to another port accordingly.