A method for monitoring a primary variable is carried out in a device having access to a set of sensors. The method includes the steps of receiving, from a network service, a series of forecasted values for the primary variable, each forecasted value being associated with one of a series of future time points; for at least one of the future time points, predicting a value for the primary variable using data of at least one secondary variable captured by a subset of the set of sensors, comparing the predicted value to the forecasted value associated with the future time point, and switching to a different subset of the set of sensors, if the predicted value deviates from the forecasted value with more than a specified threshold value.

Systems and methods for managed connectivity using local area wireless networks are provided. In certain embodiments, patching equipment in the system includes a plurality of ports configured to receive a plurality of connectors; a processing unit configured to execute instructions thereon; and a wireless communication interface, wherein the processing unit communicates connectivity information with a collection device through the wireless communication interface.

A connector arrangement includes a plug nose body; a printed circuit board positioned within a cavity of the plug nose body; and a plug cover that mounts to the plug nose body to enclose the printed circuit board within the cavity. The printed circuit board includes a storage device configured to store information pertaining to the electrical segment of communications media. The plug cover defines a plurality of slotted openings through which the second contacts are exposed. A connector assembly includes a jack module and a media reading interface configured to receive the plug. A patch panel includes multiple jack modules and multiple media reading interfaces.

To achieve multiple benefits, a high speed computing system is configured in a hierarchical manner with flexibility and re-configurability concerns maximized. This begins with a particular cabinet architecture which is specifically designed to accommodate various needs and considerations. The cabinet or rack is designed to receive various chassis assemblies depending on the particular needs and or functions involved. These may include a compute chassis, a switch chassis, or a rectifier chassis, which can be incorporated into the cabinet. Within each chassis, specific components are then inserted, with each of these components being in a subsystem configuration. For example, the compute chassis is specifically designed to receive a number of compute blades. Similarly, the switch chassis is designed to receive a number of switch blades. Lastly, the rectifier chassis is configured to receive a number of rectifiers. Collectively, the multiple blades and chassis are all configured to cooperate with one another in an efficient manner. While various subassemblies are utilized, the cabinet or rack does accommodate certain centralized functions such as cooling and power distribution.

A modular system and method for monitoring and distributing power is disclosed. A container having at least one side surface with an exit port or entrance port, a conduit transmitting through the container and an internal cavity. A container system in the internal cavity has a power distribution system, a data distribution system, and monitoring sensor monitoring container system data. A processor receives the container system data from the monitoring sensor, processes the data and transmits the processed data to the container system.

The present invention discloses a plurality of modular containers. The modular containers can comprise a first container that includes a first top surface, a first bottom surface and at least one first side surface oriented between the first top and the first bottom surface. The first container can define a first internal cavity. The modular containers can also include a container system that is located in the first internal cavity. The modular containers can include a power distribution system and a data distribution system. In addition, the modular containers can include a second container. The second container can comprise a second top surface, a second bottom surface and at least one second side surface oriented between the second top and the second bottom surface. The second container can also define second internal cavity. Further, the modular containers can include a container subsystem located in the second internal cavity. The container system can also be in communication with the container subsystem.

An embodiment of the container can include a top surface, a bottom surface and at least one side surface oriented between the top and the bottom surface. At least one side surface can define at least one exit port and at least one entrance port to the container. The container can define an internal cavity. The container can also include a load bearing member oriented on at least one of: the top surface, bottom surface or the at least one side surface. The container's top surface is load bearing, non-slip surface. First and second containers can be coupled in multiple variations and at multiple angles and power, data, fluid, or gas can be transferred and communicated between the two containers. The containers described herein can function as a replacement for standard flooring, sidewalks, and roads, or can seamlessly blend into the pre-existing environment.

A connector arrangement includes a plug nose body; a printed circuit board positioned within a cavity of the plug nose body; and a plug cover that mounts to the plug nose body to enclose the printed circuit board within the cavity. The printed circuit board includes a storage device configured to store information pertaining to the electrical segment of communications media. The plug cover defines a plurality of slotted openings through which the second contacts are exposed. A connector assembly includes a jack module and a media reading interface configured to receive the plug. A patch panel includes multiple jack modules and multiple media reading interfaces.

A preconfigured weather-resistant enclosure assembly for terminating telecommunication equipment that includes at least one access panel for gaining access to an interior portion, the interior portion of the weather-resistant enclosure including a backboard portion for mounting telecommunication equipment, and at least one internal bus bar to provide electrical ground. A set of one or more solar panels mechanically coupled to the weather-resistant enclosure. The solar panels are typically mechanically coupled to the top side of the weather-resistant enclosure. A renewable energy power management system that includes one or more outputs that provide at least one of 100 VAC-120 VAC power, 220 VAC-240 VAC, 24 VDC-48 VDC, or a combination thereof, the renewable energy power management system is positioned inside the interior portion of the weather-resistant enclosure, the renewable energy power management system includes one or more inputs electrically coupled to the set of one or more solar panels.

Systems and methods for managed connectivity using local area wireless networks are provided. In certain embodiments, patching equipment in the system includes a plurality of ports configured to receive a plurality of connectors; a processing unit configured to execute instructions thereon; and a wireless communication interface, wherein the processing unit communicates connectivity information with a collection device through the wireless communication interface.