Abstract: A method for security and safety of an industrial operation includes receiving sensor information from a plurality of sensors of an industrial operation. Sensor information from at least a portion of the plurality sensors is used for functionality of a plurality of components of the industrial operation. The method includes monitoring data traffic of the industrial operation, and deriving a baseline signature from the sensor information. The baseline signature encompasses a range of normal operating conditions. The method includes identifying an abnormal operating condition of the industrial operation based on a comparison between additional sensor information from the plurality of sensors and the baseline signature and identifying an abnormal data traffic condition.

Abstract: A method for correlating data from different sensors for product lifecycle management includes receiving sensor information from an additional sensor of a plurality of sensors of an industrial operation. The additional sensor is different from component sensors used for functionality of a component of the industrial operation. Sensor information from the additional sensor monitors conditions of a portion of the industrial operation different from sensor information of the component sensors used for the functionality of the component. The method includes deriving, using the sensor information, a correlation between an operational parameter of the component and sensor information of the additional sensor. The operational parameter is related to a predicted operational lifetime of the component.

Abstract: A multidrop system configured to be installed within a motor control center (MCC) of an industrial automation system includes a trunkline. The trunkline includes multiple multidrop make and break devices connected through a trunkline cable. Each of the multidrop make and break device includes a first network component, and a second network component. The first network component is configured to form a first subnet over the trunkline. The second network component is configured to couple a MCC withdrawable unit and form a second subnet over a branchline that connects one or more nodes within the MCC withdrawable unit. The multidrop make and break device is configured to couple the MCC withdrawable unit to, and decouple the MCC withdrawable unit from, the second network component without disrupting the first subnet.

Abstract: A method for correlating data from sensors includes receiving sensor information from a plurality of sensors of an industrial operation. Sensor information from component sensors is used for functionality of a component of the industrial operation and sensor information from additional sensors monitor conditions of a portion of the industrial operation different from the component. The method includes deriving, using the sensor information, correlations between component sensors and additional sensors and deriving a baseline signature from the sensor information and the correlations. The baseline signature encompasses a range of normal operating conditions. The method includes identifying an abnormal operating condition based on a comparison between additional sensor information and the baseline signature. The sensor information is used differently for functionality of the component than for deriving the correlations and baseline signature and identifying the abnormal operating condition.

Abstract: Various embodiments of the present technology generally relate to power topology discovery in industrial environments. More specifically, some embodiments relate to automatic power topology discovery for factories based on device data that is already recorded for other purposes. Systems and methods described herein may be used to generate an accurate electrical network topology by collecting power data from power devices that may provide real-time or recorded measurements, detecting power change events, and matching power change signatures over power events for the devices in order to calculate the likelihoods of possible topology assumptions. Power change event data is used to recursively update topology probabilities using the Bayesian formula until a system topology can be produced with satisfactory confidence.

Abstract: A multidrop system configured to be installed within a motor control center (MCC) of an industrial automation system includes a trunkline. The trunkline includes multiple multidrop make and break devices connected through a trunkline cable. Each of the multidrop make and break device includes a first network component, and a second network component. The first network component is configured to form a first subnet over the trunkline. The second network component is configured to couple a MCC withdrawable unit and form a second subnet over a branchline that connects one or more nodes within the MCC withdrawable unit. The multidrop make and break device is configured to couple the MCC withdrawable unit to, and decouple the MCC withdrawable unit from, the second network component without disrupting the first subnet.

Abstract: A method for security and safety of an industrial operation includes receiving sensor information from a plurality of sensors of an industrial operation. Sensor information from at least a portion of the plurality sensors is used for functionality of a plurality of components of the industrial operation. The method includes monitoring data traffic of the industrial operation, and deriving a baseline signature from the sensor information. The baseline signature encompasses a range of normal operating conditions. The method includes identifying an abnormal operating condition of the industrial operation based on a comparison between additional sensor information from the plurality of sensors and the baseline signature and identifying an abnormal data traffic condition.

Abstract: A method for correlating data from different sensors for product lifecycle management includes receiving sensor information from an additional sensor of a plurality of sensors of an industrial operation. The additional sensor is different from component sensors used for functionality of a component of the industrial operation. Sensor information from the additional sensor monitors conditions of a portion of the industrial operation different from sensor information of the component sensors used for the functionality of the component. The method includes deriving, using the sensor information, a correlation between an operational parameter of the component and sensor information of the additional sensor. The operational parameter is related to a predicted operational lifetime of the component.

Abstract: A method for correlating data from sensors includes receiving sensor information from a plurality of sensors of an industrial operation. Sensor information from component sensors is used for functionality of a component of the industrial operation and sensor information from additional sensors monitor conditions of a portion of the industrial operation different from the component. The method includes deriving, using the sensor information, correlations between component sensors and additional sensors and deriving a baseline signature from the sensor information and the correlations. The baseline signature encompasses a range of normal operating conditions. The method includes identifying an abnormal operating condition based on a comparison between additional sensor information and the baseline signature. The sensor information is used differently for functionality of the component than for deriving the correlations and baseline signature and identifying the abnormal operating condition.

Abstract: For device configuration and monitoring, a processor receives configuration settings from an electronic device via the electronic device interface. The processor converts the configuration settings to hardware settings for a target device. The processor communicates the hardware settings to the target device via a target device interface.

Abstract: Various embodiments of the present technology generally relate to power topology discovery in industrial environments. More specifically, some embodiments relate to automatic power topology discovery for factories based on device data that is already recorded for other purposes. Systems and methods described herein may be used to generate an accurate electrical network topology by collecting power data from power devices that may provide real-time or recorded measurements, detecting power change events, and matching power change signatures over power events for the devices in order to calculate the likelihoods of possible topology assumptions. Power change event data is used to recursively update topology probabilities using the Bayesian formula until a system topology can be produced with satisfactory confidence.

Abstract: For device configuration and monitoring, a processor receives configuration settings from an electronic device via the electronic device interface. The processor converts the configuration settings to hardware settings for a target device. The processor communicates the hardware settings to the target device via a target device interface.

Abstract: Systems, methods and apparatus for controlling a control network system coupled to an intelligent power tap are disclosed. The method includes sensing at least one of a current signal and a voltage signal, determining that the current signal or the voltage signal is not within a preset range for a predefined period of time, sending a first warning message to the control network system, determining whether to shut off the network power or the switched power, and determining whether to broadcast a second warning message.

Abstract: Systems, methods and apparatus for controlling a control network system coupled to an intelligent power tap are disclosed. The method includes sensing at least one of a current signal and a voltage signal, determining that the current signal or the voltage signal is not within a preset range for a predefined period of time, sending a first warning message to the control network system, determining whether to shut off the network power or the switched power, and determining whether to broadcast a second warning message.

Abstract: Systems, methods and apparatus for multiple network addressing modes are disclosed. The method includes selecting one of an automap full mode, an automap-by-type full mode, an automap light mode, an automap-by-type light mode and a manual node commissioning mode for determining and assigning the node addresses for the network devices, determining and assigning the node addresses for the network devices based on the automap full mode, determining and assigning the node addresses for the network devices based on the automap-by-type full mode, determining and assigning the node addresses for newly added network devices to an existing network based on the automap light mode, determining and assigning the node addresses for the newly added network devices to the existing network based on the automap-by-type light mode, and determining and assigning the node addresses for the network devices based on the manual node commissioning mode.

Abstract: Systems and methods for providing diagnostic information by an intelligent power tap is disclosed. The intelligent power tap includes a circuit board. The intelligent power tap includes a microcontroller disposed on the circuit board, where the microcontroller is configured to report the geographical location of the intelligent power tap. The intelligent power tap includes a physical layer network interface connected to the microcontroller and the physical network. The intelligent power tap includes a switch controlled by the microcontroller, where the switch is capable of shutting off a network power to be injected into the network system.

Abstract: Systems and methods for providing diagnostic information by an intelligent power tap is disclosed. The power tap includes a circuit board and a microcontroller disposed on the circuit board. The microcontroller is configured to provide a status report of the intelligent power tap. The power tap further includes a physical layer network interface connected to the microcontroller and the physical network. The intelligent power tap is configured to inject at least one of a network power and a switched power into the network system.

Abstract: Systems and methods are provided for a power tap with adjustable configuration. The power tap includes a circuit board that acts on the adjustable configuration to define the function of the power tap in the system. The power tap may include a microcontroller or a set of discrete logic disposed on a circuit board connected to an adjustable configuration mechanism, which defines the intelligent power tap's function in the network system.

Abstract: The disclosed embodiments relate generally to a modular connector for a multi-conductor ribbon cable provided for power and data transmission to a network of devices. The modular connector is coupled to the conductors in the ribbon cable by insulation displacement members. The connector contains both fixed and movable conductor punches used to configure a network interface.

Abstract: Systems, methods and apparatus for multiple network addressing modes are disclosed. The method includes selecting one of an automap full mode, an automap-by-type full mode, an automap light mode, an automap-by-type light mode and a manual node commissioning mode for determining and assigning the node addresses for the network devices, determining and assigning the node addresses for the network devices based on the automap full mode, determining and assigning the node addresses for the network devices based on the automap-by-type full mode, determining and assigning the node addresses for newly added network devices to an existing network based on the automap light mode, determining and assigning the node addresses for the newly added network devices to the existing network based on the automap-by-type light mode, and determining and assigning the node addresses for the network devices based on the manual node commissioning mode.