Abstract: A system includes server that performs operations including obtaining, from sensors, measurements of physical parameters related to electrical power transmission and data transfer corresponding to a Broadband over Power Line (BPL) data links and a multi-use power interface configured to be electrically and communicatively coupled to a vehicle via the BPL data links. The operations also include receiving identification and location information, and a timestamp associated with a connector of the multi-use power interface, and then storing the measurements, the identification and location information, and the timestamp. The operations further include detecting a change of the connector, and identifying trends in parameters by comparing the measurements and the identification and location information to historical data.

Abstract: A system includes a multi-use power interface configured to be electrically and communicatively coupled to a vehicle via Broadband over Power Line (BPL) data links. The system also includes sensors configured to collect power quality data and load management data for the BPL data links and the multi-use power interface. The multi-use power interface includes a user interface, a processor, and a memory having instructions stored thereon that, when executed by the processor, cause the multi-use power interface to perform operations. The operations include receiving power quality data and load management data from the sensors. The operations also include determining, based on the received data, functional health statuses of the multi-use power interface and the BPL data links. The operations further include transmitting the functional health statuses, the power quality data, and the load management data to a data store, and indicating, in the user interface, the functional health statuses.

Abstract: A system includes server that performs operations including obtaining, from sensors, measurements of physical parameters related to electrical power transmission and data transfer corresponding to a Broadband over Power Line (BPL) data links and a multi-use power interface configured to be electrically and communicatively coupled to a vehicle via the BPL data links. The operations also include receiving identification and location information, and a timestamp associated with a connector of the multi-use power interface, and then storing the measurements, the identification and location information, and the timestamp. The operations further include detecting a change of the connector, and identifying trends in parameters by comparing the measurements and the identification and location information to historical data.

Abstract: A system includes a memory configured to store instructions and a processor that is coupled to the memory. The processor is configured to determine, based on data received from one or more of a reference tag or a positioning sensor tag, a change in a first orientation or position of a portal system platform. The processor is further configured to determine, based on detection data, a second orientation or position of a wireless identification (ID) tag or a change in the second orientation or position. The processor is further configured to determine whether the second orientation or position is valid based on the received data and to perform a response action responsive to determining that the second orientation or position is invalid due to the change of the first orientation or position of the portal system platform.

Abstract: A system for allocating wireless frequency spectrum is provided. The system may include one or more location tags attached on one or more foreign network devices and domestic network devices, one or more real-time location tracking system configured to detect the one or more location tags, and at least one control unit in communication with at least one domestic network device. The control unit may be configured to query one or more proximity policies associated with the foreign network devices and the domestic network devices, apply a modified network configuration to one or more of the domestic network devices when at least one associated proximity policy is discovered, and restore a default network configuration, or setting the modified network configuration as a new default network configuration, to the one or more of the domestic network devices when the discovered proximity policy is no longer effective.

Abstract: A system includes server that performs operations including obtaining, from sensors, measurements of physical parameters related to electrical power transmission and data transfer corresponding to a Broadband over Power Line (BPL) data links and a multi-use power interface configured to be electrically and communicatively coupled to a vehicle via the BPL data links. The operations also include receiving identification and location information, and a timestamp associated with a connector of the multi-use power interface, and then storing the measurements, the identification and location information, and the timestamp. The operations further include detecting a change of the connector, and identifying trends in parameters by comparing the measurements and the identification and location information to historical data.

Abstract: A system includes server that performs operations including obtaining, from sensors, measurements of physical parameters related to electrical power transmission and data transfer corresponding to a Broadband over Power Line (BPL) data links and a multi-use power interface configured to be electrically and communicatively coupled to a vehicle via the BPL data links. The operations also include receiving identification and location information, and a timestamp associated with a connector of the multi-use power interface, and then storing the measurements, the identification and location information, and the timestamp. The operations further include detecting a change of the connector, and identifying trends in parameters by comparing the measurements and the identification and location information to historical data.

Abstract: A system includes a multi-use power interface configured to be electrically and communicatively coupled to a vehicle via Broadband over Power Line (BPL) data links. The system also includes sensors configured to collect power quality data and load management data for the BPL data links and the multi-use power interface. The multi-use power interface includes a user interface, a processor, and a memory having instructions stored thereon that, when executed by the processor, cause the multi-use power interface to perform operations. The operations include receiving power quality data and load management data from the sensors. The operations also include determining, based on the received data, functional health statuses of the multi-use power interface and the BPL data links. The operations further include transmitting the functional health statuses, the power quality data, and the load management data to a data store, and indicating, in the user interface, the functional health statuses.

Abstract: A system includes a multi-use power interface configured to be electrically and communicatively coupled to a vehicle via Broadband over Power Line (BPL) data links. The system also includes sensors configured to collect power quality data and load management data for the BPL data links and the multi-use power interface. The multi-use power interface includes a user interface, a processor, and a memory having instructions stored thereon that, when executed by the processor, cause the multi-use power interface to perform operations. The operations include receiving power quality data and load management data from the sensors. The operations also include determining, based on the received data, functional health statuses of the multi-use power interface and the BPL data links. The operations further include transmitting the functional health statuses, the power quality data, and the load management data to a data store, and indicating, in the user interface, the functional health statuses.

Abstract: A system and method is described for automated system health status determination, performance calibration, and configuration of a plurality of wireless identification (wireless ID) transceivers (or receivers) to prevent cross-receptions of wireless ID tags in adjacent wireless signal reception areas. Test wireless ID tags are positioned within the wireless signal reception area associated with each of the wireless ID antennas. The configuration parameters for each wireless ID transceiver are adjusted until only data from test wireless ID tags within the wireless signal reception area of the wireless ID antennas associated with that wireless ID transceiver are received by that wireless ID transceiver. Each wireless ID transceiver is configured with the configuration parameters that result in only data from the test wireless ID tags within the wireless signal reception area of the wireless ID antennas associated with that test wireless ID transceiver being received by that wireless ID transceiver.

Abstract: A system and method is described for automated system health status determination, performance calibration, and configuration of a plurality of wireless identification (wireless ID) transceivers (or receivers) to prevent cross-receptions of wireless ID tags in adjacent wireless signal reception areas. Test wireless ID tags are positioned within the wireless signal reception area associated with each of the wireless ID antennas. The configuration parameters for each wireless ID transceiver are adjusted until only data from test wireless ID tags within the wireless signal reception area of the wireless ID antennas associated with that wireless ID transceiver are received by that wireless ID transceiver. Each wireless ID transceiver is configured with the configuration parameters that result in only data from the test wireless ID tags within the wireless signal reception area of the wireless ID antennas associated with that test wireless ID transceiver being received by that wireless ID transceiver.

Abstract: A method is presented in which a system reduces the risk of an advanced persistent threat (“APT”) detected at one or more network devices by implementing one or more mitigation actions depending on the nature of the detected threat. Accordingly, in response to detecting the risk of an APT at one or more network devices, a centralized controller implements one or more mitigation actions to minimize the vulnerability of an enterprise network to unauthorized access to one or more network resources. A centralized controller may therefore instruct one or more network devices to take appropriate mitigation actions depending on the nature of an APT detected on one or more network devices.

Abstract: A system for allocating wireless frequency spectrum is provided. The system may include one or more location tags attached on one or more foreign network devices and domestic network devices, one or more real-time location tracking system configured to detect the one or more location tags, and at least one control unit in communication with at least one domestic network device. The control unit may be configured to query one or more proximity policies associated with the foreign network devices and the domestic network devices, apply a modified network configuration to one or more of the domestic network devices when at least one associated proximity policy is discovered, and restore a default network configuration, or setting the modified network configuration as a new default network configuration, to the one or more of the domestic network devices when the discovered proximity policy is no longer effective.

Abstract: A method is presented in which a system reduces the risk of an advanced persistent threat (“APT”) detected at one or more network devices by implementing one or more mitigation actions depending on the nature of the detected threat. Accordingly, in response to detecting the risk of an APT at one or more network devices, a centralized controller implements one or more mitigation actions to minimize the vulnerability of an enterprise network to unauthorized access to one or more network resources. A centralized controller may therefore instruct one or more network devices to take appropriate mitigation actions depending on the nature of an APT detected on one or more network devices.

Abstract: A sequential sampling tool that executes advanced sequential protocols on a portable platform. The system includes a computer and software code compiled with well-known statistical and graphical user interface packages. The sampling and testing tool supports SPRT, 2-SPRT, and sequential Bayes sampling protocols for a variety of statistical distributions, including Bernoulli, binomial, Poisson, negative binomial, and normal distributions. The user has easy access to properties of the statistical design, such as average sample size curve, the operating characteristic curve, and the Type-1 and Type-2 error rates. The system also displays two boundary lines for the design, and allows the user to plot and visualize each observation point one-at-a-time as each sample unit is taken and counted.