In an example implementation, a method includes receiving, at a processor, historical pole data records representing utility poles and having one or more pole attributes. Likewise, a method includes generating one or more pole subpopulations of historical pole data records having at least one common pole attribute. Further, the method includes performing a predictive algorithm on each pole subpopulation. Finally, the method includes determining, based on a predictive algorithm, the number of poles in the particular subpopulation that are likely to meet a rejection condition within a specified time frame. In another example implementation, a method includes receiving a sample pole data record representing a particular sample data pole and determining the likelihood of the particular sample utility pole meeting a rejection condition within a specified time frame.

In an example implementation, a method includes receiving, at a processor, historical pole data records representing utility poles and having one or more pole attributes. Likewise, a method includes generating one or more pole subpopulations of historical pole data records having at least one common pole attribute. Further, the method includes performing a predictive algorithm on each pole subpopulation. Finally, the method includes determining, based on a predictive algorithm, the number of poles in the particular subpopulation that are likely to meet a rejection condition within a specified time frame. In another example implementation, a method includes receiving a sample pole data record representing a particular sample data pole and determining the likelihood of the particular sample utility pole meeting a rejection condition within a specified time frame.

Apparatus and methods for signal boosters for vehicles are provided. In certain embodiments, a vehicle signal booster system includes an interior unit including a mobile station antenna that receives an RF uplink signal and transmits a boosted RF downlink signal. The vehicle signal booster system further includes a top unit including a base station antenna that receives an RF downlink signal and transmits a boosted RF uplink signal. The vehicle signal booster system further includes booster circuitry that generates the boosted RF downlink signal based on amplifying one or more downlink channels of the RF downlink signal, and that generates the boosted RF uplink signal based on amplifying one or more uplink channels of the RF uplink signal. The booster circuitry is implemented in the top unit or in the top unit and the interior unit.

Aspects of the subject disclosure may include, a system that facilitates directing a first electromagnetic wave to a device positioned along a transmission medium, the device facilitating a perturbation of the first electromagnetic wave, and the first electromagnetic wave having a first field intensity near an outer surface of the transmission medium, and generating, by the device, a second electromagnetic wave having a second field intensity near the outer surface of the transmission medium that is lower than the first field intensity of the first electromagnetic wave. Other embodiments are disclosed.

Aspects of the subject disclosure may include, a system that facilitates directing a first electromagnetic wave to a device positioned along a transmission medium, the device facilitating a perturbation of the first electromagnetic wave, and the first electromagnetic wave having a first field intensity near an outer surface of the transmission medium, and generating, by the device, a second electromagnetic wave having a second field intensity near the outer surface of the transmission medium that is lower than the first field intensity of the first electromagnetic wave. Other embodiments are disclosed.

Selecting a communication route between a first and a second node device of a mesh electrical supply network using powerline and/or radio-frequency communications is described. A route cost is obtained for each possible communication route. A communication route of the lowest route cost is selected. For a given route, the route cost is the sum of the link costs between successive node devices on the route, the link cost between two successive node devices is a weighted sum between a maximum value from a link cost in a forward direction and a link cost in a backward direction and a ratio between a number of active routes and a maximum number of active routes. A link cost in a given direction depends on the cost of the link, in the given direction, calculated for each frequency band of frequency bands used by the two successive node devices for communicating.

Selecting a communication route between a first and a second node device of a mesh electrical supply network using powerline and/or radio-frequency communications is described. A route cost is obtained for each possible communication route. A communication route of the lowest route cost is selected. For a given route, the route cost is the sum of the link costs between successive node devices on the route, the link cost between two successive node devices is a weighted sum between a maximum value from a link cost in a forward direction and a link cost in a backward direction and a ratio between a number of active routes and a maximum number of active routes. A link cost in a given direction depends on the cost of the link, in the given direction, calculated for each frequency band of frequency bands used by the two successive node devices for communicating.

Systems and methods for enabling communication in a downhole power and communications system installed in a well, where one or more components of a wired backbone of the system have failed. Equipment positioned at the surface of a well is connected to a wired power and communication backbone that has one or more conductors and one or more nodes with standardized interfaces that enable downhole devices to be interchangeably connected to the wired backbone. When the wired backbone has failed at one or more points, preventing wired communications between the surface equipment and one or more downhole devices installed at the nodes, one or more wireless-enabled modules are installed at corresponding nodes of the wired backbone to establish wireless channels that bridge the failed portion of the wired backbone and thereby enable communication between the surface equipment and the downhole devices.

In certain embodiments, an assembly has intermediate pods magnetically, but not galvanically, coupled along an electrically conductive cable. Each pod has a magnetic core surrounding and inductively coupled to the cable and one or more coils inductively coupled to the magnetic core. The pod transmits, for example, outgoing current pulses on the cable by inducing electrical signals in the cable using a transmitter coil and the magnetic core. In addition, the pod repeats, for example, incoming current pulses on the cable by inducing electrical signals in the cable using the transmitter coil and the magnetic core, based on electrical signals induced in a receiver coil via the magnetic core by the incoming current pulses. Such an assembly can function as a data collection system for scientific research and/or as an early-warning system for events, such as earthquakes and tsunamis, without having to modify the cable itself.

Systems and methods for signal boosting in serial interfaces are provided. In some implementations, a system for boosting signals comprises boosting circuitry. The boosting circuitry may comprise at least one boosting capacitor configured to be operatively coupled to a voltage supply during a charging phase and configured to be operatively coupled to the at least one line of a signal transmission line during a discharging phase, wherein, during the discharging phase, the at least one boosting capacitor boosts a voltage of the one or more signals transmitted on the at least one line. The boosting circuitry may comprise switching circuitry configured to switch the at least one boosting capacitor between from being operatively coupled to the voltage supply to being operatively coupled to the at least one line of the signal transmission line.